""" Generated from FAST OutListParameters.xlsx files with openfast_io/openfast_io/create_output_vars.py """


""" AeroDyn """
AeroDyn = {}

# Tower
AeroDyn['TwN1VUndx']          = False     # (m/s); Undisturbed x-component wind velocity at Tw node 1; local tower coordinate system
AeroDyn['TwN1VUndy']          = False     # (m/s); Undisturbed y-component wind velocity at Tw node 1; local tower coordinate system
AeroDyn['TwN1VUndz']          = False     # (m/s); Undisturbed z-component wind velocity at Tw node 1; local tower coordinate system
AeroDyn['TwN2VUndx']          = False     # (m/s); Undisturbed x-component wind velocity at Tw node 2; local tower coordinate system
AeroDyn['TwN2VUndy']          = False     # (m/s); Undisturbed y-component wind velocity at Tw node 2; local tower coordinate system
AeroDyn['TwN2VUndz']          = False     # (m/s); Undisturbed z-component wind velocity at Tw node 2; local tower coordinate system
AeroDyn['TwN3VUndx']          = False     # (m/s); Undisturbed x-component wind velocity at Tw node 3; local tower coordinate system
AeroDyn['TwN3VUndy']          = False     # (m/s); Undisturbed y-component wind velocity at Tw node 3; local tower coordinate system
AeroDyn['TwN3VUndz']          = False     # (m/s); Undisturbed z-component wind velocity at Tw node 3; local tower coordinate system
AeroDyn['TwN4VUndx']          = False     # (m/s); Undisturbed x-component wind velocity at Tw node 4; local tower coordinate system
AeroDyn['TwN4VUndy']          = False     # (m/s); Undisturbed y-component wind velocity at Tw node 4; local tower coordinate system
AeroDyn['TwN4VUndz']          = False     # (m/s); Undisturbed z-component wind velocity at Tw node 4; local tower coordinate system
AeroDyn['TwN5VUndx']          = False     # (m/s); Undisturbed x-component wind velocity at Tw node 5; local tower coordinate system
AeroDyn['TwN5VUndy']          = False     # (m/s); Undisturbed y-component wind velocity at Tw node 5; local tower coordinate system
AeroDyn['TwN5VUndz']          = False     # (m/s); Undisturbed z-component wind velocity at Tw node 5; local tower coordinate system
AeroDyn['TwN6VUndx']          = False     # (m/s); Undisturbed x-component wind velocity at Tw node 6; local tower coordinate system
AeroDyn['TwN6VUndy']          = False     # (m/s); Undisturbed y-component wind velocity at Tw node 6; local tower coordinate system
AeroDyn['TwN6VUndz']          = False     # (m/s); Undisturbed z-component wind velocity at Tw node 6; local tower coordinate system
AeroDyn['TwN7VUndx']          = False     # (m/s); Undisturbed x-component wind velocity at Tw node 7; local tower coordinate system
AeroDyn['TwN7VUndy']          = False     # (m/s); Undisturbed y-component wind velocity at Tw node 7; local tower coordinate system
AeroDyn['TwN7VUndz']          = False     # (m/s); Undisturbed z-component wind velocity at Tw node 7; local tower coordinate system
AeroDyn['TwN8VUndx']          = False     # (m/s); Undisturbed x-component wind velocity at Tw node 8; local tower coordinate system
AeroDyn['TwN8VUndy']          = False     # (m/s); Undisturbed y-component wind velocity at Tw node 8; local tower coordinate system
AeroDyn['TwN8VUndz']          = False     # (m/s); Undisturbed z-component wind velocity at Tw node 8; local tower coordinate system
AeroDyn['TwN9VUndx']          = False     # (m/s); Undisturbed x-component wind velocity at Tw node 9; local tower coordinate system
AeroDyn['TwN9VUndy']          = False     # (m/s); Undisturbed y-component wind velocity at Tw node 9; local tower coordinate system
AeroDyn['TwN9VUndz']          = False     # (m/s); Undisturbed z-component wind velocity at Tw node 9; local tower coordinate system
AeroDyn['TwN1STVx']           = False     # (m/s); Structural translational velocity x-component at Tw node 1; local tower coordinate system
AeroDyn['TwN1STVy']           = False     # (m/s); Structural translational velocity y-component at Tw node 1; local tower coordinate system
AeroDyn['TwN1STVz']           = False     # (m/s); Structural translational velocity z-component at Tw node 1; local tower coordinate system
AeroDyn['TwN2STVx']           = False     # (m/s); Structural translational velocity x-component at Tw node 2; local tower coordinate system
AeroDyn['TwN2STVy']           = False     # (m/s); Structural translational velocity y-component at Tw node 2; local tower coordinate system
AeroDyn['TwN2STVz']           = False     # (m/s); Structural translational velocity z-component at Tw node 2; local tower coordinate system
AeroDyn['TwN3STVx']           = False     # (m/s); Structural translational velocity x-component at Tw node 3; local tower coordinate system
AeroDyn['TwN3STVy']           = False     # (m/s); Structural translational velocity y-component at Tw node 3; local tower coordinate system
AeroDyn['TwN3STVz']           = False     # (m/s); Structural translational velocity z-component at Tw node 3; local tower coordinate system
AeroDyn['TwN4STVx']           = False     # (m/s); Structural translational velocity x-component at Tw node 4; local tower coordinate system
AeroDyn['TwN4STVy']           = False     # (m/s); Structural translational velocity y-component at Tw node 4; local tower coordinate system
AeroDyn['TwN4STVz']           = False     # (m/s); Structural translational velocity z-component at Tw node 4; local tower coordinate system
AeroDyn['TwN5STVx']           = False     # (m/s); Structural translational velocity x-component at Tw node 5; local tower coordinate system
AeroDyn['TwN5STVy']           = False     # (m/s); Structural translational velocity y-component at Tw node 5; local tower coordinate system
AeroDyn['TwN5STVz']           = False     # (m/s); Structural translational velocity z-component at Tw node 5; local tower coordinate system
AeroDyn['TwN6STVx']           = False     # (m/s); Structural translational velocity x-component at Tw node 6; local tower coordinate system
AeroDyn['TwN6STVy']           = False     # (m/s); Structural translational velocity y-component at Tw node 6; local tower coordinate system
AeroDyn['TwN6STVz']           = False     # (m/s); Structural translational velocity z-component at Tw node 6; local tower coordinate system
AeroDyn['TwN7STVx']           = False     # (m/s); Structural translational velocity x-component at Tw node 7; local tower coordinate system
AeroDyn['TwN7STVy']           = False     # (m/s); Structural translational velocity y-component at Tw node 7; local tower coordinate system
AeroDyn['TwN7STVz']           = False     # (m/s); Structural translational velocity z-component at Tw node 7; local tower coordinate system
AeroDyn['TwN8STVx']           = False     # (m/s); Structural translational velocity x-component at Tw node 8; local tower coordinate system
AeroDyn['TwN8STVy']           = False     # (m/s); Structural translational velocity y-component at Tw node 8; local tower coordinate system
AeroDyn['TwN8STVz']           = False     # (m/s); Structural translational velocity z-component at Tw node 8; local tower coordinate system
AeroDyn['TwN9STVx']           = False     # (m/s); Structural translational velocity x-component at Tw node 9; local tower coordinate system
AeroDyn['TwN9STVy']           = False     # (m/s); Structural translational velocity y-component at Tw node 9; local tower coordinate system
AeroDyn['TwN9STVz']           = False     # (m/s); Structural translational velocity z-component at Tw node 9; local tower coordinate system
AeroDyn['TwN1Vrel']           = False     # (m/s); Relative wind speed at Tw node 1; 
AeroDyn['TwN2Vrel']           = False     # (m/s); Relative wind speed at Tw node 2; 
AeroDyn['TwN3Vrel']           = False     # (m/s); Relative wind speed at Tw node 3; 
AeroDyn['TwN4Vrel']           = False     # (m/s); Relative wind speed at Tw node 4; 
AeroDyn['TwN5Vrel']           = False     # (m/s); Relative wind speed at Tw node 5; 
AeroDyn['TwN6Vrel']           = False     # (m/s); Relative wind speed at Tw node 6; 
AeroDyn['TwN7Vrel']           = False     # (m/s); Relative wind speed at Tw node 7; 
AeroDyn['TwN8Vrel']           = False     # (m/s); Relative wind speed at Tw node 8; 
AeroDyn['TwN9Vrel']           = False     # (m/s); Relative wind speed at Tw node 9; 
AeroDyn['TwN1DynP']           = False     # (Pa); Dynamic Pressure at Tw node 1; 
AeroDyn['TwN2DynP']           = False     # (Pa); Dynamic Pressure at Tw node 2; 
AeroDyn['TwN3DynP']           = False     # (Pa); Dynamic Pressure at Tw node 3; 
AeroDyn['TwN4DynP']           = False     # (Pa); Dynamic Pressure at Tw node 4; 
AeroDyn['TwN5DynP']           = False     # (Pa); Dynamic Pressure at Tw node 5; 
AeroDyn['TwN6DynP']           = False     # (Pa); Dynamic Pressure at Tw node 6; 
AeroDyn['TwN7DynP']           = False     # (Pa); Dynamic Pressure at Tw node 7; 
AeroDyn['TwN8DynP']           = False     # (Pa); Dynamic Pressure at Tw node 8; 
AeroDyn['TwN9DynP']           = False     # (Pa); Dynamic Pressure at Tw node 9; 
AeroDyn['TwN1Re']             = False     # (-); Reynolds number (in millions) at Tw node 1; 
AeroDyn['TwN2Re']             = False     # (-); Reynolds number (in millions) at Tw node 2; 
AeroDyn['TwN3Re']             = False     # (-); Reynolds number (in millions) at Tw node 3; 
AeroDyn['TwN4Re']             = False     # (-); Reynolds number (in millions) at Tw node 4; 
AeroDyn['TwN5Re']             = False     # (-); Reynolds number (in millions) at Tw node 5; 
AeroDyn['TwN6Re']             = False     # (-); Reynolds number (in millions) at Tw node 6; 
AeroDyn['TwN7Re']             = False     # (-); Reynolds number (in millions) at Tw node 7; 
AeroDyn['TwN8Re']             = False     # (-); Reynolds number (in millions) at Tw node 8; 
AeroDyn['TwN9Re']             = False     # (-); Reynolds number (in millions) at Tw node 9; 
AeroDyn['TwN1M']              = False     # (-); Mach number at Tw node 1; 
AeroDyn['TwN2M']              = False     # (-); Mach number at Tw node 2; 
AeroDyn['TwN3M']              = False     # (-); Mach number at Tw node 3; 
AeroDyn['TwN4M']              = False     # (-); Mach number at Tw node 4; 
AeroDyn['TwN5M']              = False     # (-); Mach number at Tw node 5; 
AeroDyn['TwN6M']              = False     # (-); Mach number at Tw node 6; 
AeroDyn['TwN7M']              = False     # (-); Mach number at Tw node 7; 
AeroDyn['TwN8M']              = False     # (-); Mach number at Tw node 8; 
AeroDyn['TwN9M']              = False     # (-); Mach number at Tw node 9; 
AeroDyn['TwN1Fdx']            = False     # (N/m); x-component of drag force per unit length at Tw node 1; local tower coordinate system
AeroDyn['TwN2Fdx']            = False     # (N/m); x-component of drag force per unit length at Tw node 2; local tower coordinate system
AeroDyn['TwN3Fdx']            = False     # (N/m); x-component of drag force per unit length at Tw node 3; local tower coordinate system
AeroDyn['TwN4Fdx']            = False     # (N/m); x-component of drag force per unit length at Tw node 4; local tower coordinate system
AeroDyn['TwN5Fdx']            = False     # (N/m); x-component of drag force per unit length at Tw node 5; local tower coordinate system
AeroDyn['TwN6Fdx']            = False     # (N/m); x-component of drag force per unit length at Tw node 6; local tower coordinate system
AeroDyn['TwN7Fdx']            = False     # (N/m); x-component of drag force per unit length at Tw node 7; local tower coordinate system
AeroDyn['TwN8Fdx']            = False     # (N/m); x-component of drag force per unit length at Tw node 8; local tower coordinate system
AeroDyn['TwN9Fdx']            = False     # (N/m); x-component of drag force per unit length at Tw node 9; local tower coordinate system
AeroDyn['TwN1Fdy']            = False     # (N/m); y-component of drag force per unit length at Tw node 1; local tower coordinate system
AeroDyn['TwN2Fdy']            = False     # (N/m); y-component of drag force per unit length at Tw node 2; local tower coordinate system
AeroDyn['TwN3Fdy']            = False     # (N/m); y-component of drag force per unit length at Tw node 3; local tower coordinate system
AeroDyn['TwN4Fdy']            = False     # (N/m); y-component of drag force per unit length at Tw node 4; local tower coordinate system
AeroDyn['TwN5Fdy']            = False     # (N/m); y-component of drag force per unit length at Tw node 5; local tower coordinate system
AeroDyn['TwN6Fdy']            = False     # (N/m); y-component of drag force per unit length at Tw node 6; local tower coordinate system
AeroDyn['TwN7Fdy']            = False     # (N/m); y-component of drag force per unit length at Tw node 7; local tower coordinate system
AeroDyn['TwN8Fdy']            = False     # (N/m); y-component of drag force per unit length at Tw node 8; local tower coordinate system
AeroDyn['TwN9Fdy']            = False     # (N/m); y-component of drag force per unit length at Tw node 9; local tower coordinate system
AeroDyn['TwN1Fbx']            = False     # (N/m); x-component of buoyant force per unit length at Tw node 1; local tower coordinate system
AeroDyn['TwN2Fbx']            = False     # (N/m); x-component of buoyant force per unit length at Tw node 2; local tower coordinate system
AeroDyn['TwN3Fbx']            = False     # (N/m); x-component of buoyant force per unit length at Tw node 3; local tower coordinate system
AeroDyn['TwN4Fbx']            = False     # (N/m); x-component of buoyant force per unit length at Tw node 4; local tower coordinate system
AeroDyn['TwN5Fbx']            = False     # (N/m); x-component of buoyant force per unit length at Tw node 5; local tower coordinate system
AeroDyn['TwN6Fbx']            = False     # (N/m); x-component of buoyant force per unit length at Tw node 6; local tower coordinate system
AeroDyn['TwN7Fbx']            = False     # (N/m); x-component of buoyant force per unit length at Tw node 7; local tower coordinate system
AeroDyn['TwN8Fbx']            = False     # (N/m); x-component of buoyant force per unit length at Tw node 8; local tower coordinate system
AeroDyn['TwN9Fbx']            = False     # (N/m); x-component of buoyant force per unit length at Tw node 9; local tower coordinate system
AeroDyn['TwN1Fby']            = False     # (N/m); y-component of buoyant force per unit length at Tw node 1; local tower coordinate system
AeroDyn['TwN2Fby']            = False     # (N/m); y-component of buoyant force per unit length at Tw node 2; local tower coordinate system
AeroDyn['TwN3Fby']            = False     # (N/m); y-component of buoyant force per unit length at Tw node 3; local tower coordinate system
AeroDyn['TwN4Fby']            = False     # (N/m); y-component of buoyant force per unit length at Tw node 4; local tower coordinate system
AeroDyn['TwN5Fby']            = False     # (N/m); y-component of buoyant force per unit length at Tw node 5; local tower coordinate system
AeroDyn['TwN6Fby']            = False     # (N/m); y-component of buoyant force per unit length at Tw node 6; local tower coordinate system
AeroDyn['TwN7Fby']            = False     # (N/m); y-component of buoyant force per unit length at Tw node 7; local tower coordinate system
AeroDyn['TwN8Fby']            = False     # (N/m); y-component of buoyant force per unit length at Tw node 8; local tower coordinate system
AeroDyn['TwN9Fby']            = False     # (N/m); y-component of buoyant force per unit length at Tw node 9; local tower coordinate system
AeroDyn['TwN1Fbz']            = False     # (N/m); z-component of buoyant force per unit length at Tw node 1; local tower coordinate system
AeroDyn['TwN2Fbz']            = False     # (N/m); z-component of buoyant force per unit length at Tw node 2; local tower coordinate system
AeroDyn['TwN3Fbz']            = False     # (N/m); z-component of buoyant force per unit length at Tw node 3; local tower coordinate system
AeroDyn['TwN4Fbz']            = False     # (N/m); z-component of buoyant force per unit length at Tw node 4; local tower coordinate system
AeroDyn['TwN5Fbz']            = False     # (N/m); z-component of buoyant force per unit length at Tw node 5; local tower coordinate system
AeroDyn['TwN6Fbz']            = False     # (N/m); z-component of buoyant force per unit length at Tw node 6; local tower coordinate system
AeroDyn['TwN7Fbz']            = False     # (N/m); z-component of buoyant force per unit length at Tw node 7; local tower coordinate system
AeroDyn['TwN8Fbz']            = False     # (N/m); z-component of buoyant force per unit length at Tw node 8; local tower coordinate system
AeroDyn['TwN9Fbz']            = False     # (N/m); z-component of buoyant force per unit length at Tw node 9; local tower coordinate system
AeroDyn['TwN1Mbx']            = False     # (N-m/m); x-component of buoyant moment per unit length at Tw node 1; local tower coordinate system
AeroDyn['TwN2Mbx']            = False     # (N-m/m); x-component of buoyant moment per unit length at Tw node 2; local tower coordinate system
AeroDyn['TwN3Mbx']            = False     # (N-m/m); x-component of buoyant moment per unit length at Tw node 3; local tower coordinate system
AeroDyn['TwN4Mbx']            = False     # (N-m/m); x-component of buoyant moment per unit length at Tw node 4; local tower coordinate system
AeroDyn['TwN5Mbx']            = False     # (N-m/m); x-component of buoyant moment per unit length at Tw node 5; local tower coordinate system
AeroDyn['TwN6Mbx']            = False     # (N-m/m); x-component of buoyant moment per unit length at Tw node 6; local tower coordinate system
AeroDyn['TwN7Mbx']            = False     # (N-m/m); x-component of buoyant moment per unit length at Tw node 7; local tower coordinate system
AeroDyn['TwN8Mbx']            = False     # (N-m/m); x-component of buoyant moment per unit length at Tw node 8; local tower coordinate system
AeroDyn['TwN9Mbx']            = False     # (N-m/m); x-component of buoyant moment per unit length at Tw node 9; local tower coordinate system
AeroDyn['TwN1Mby']            = False     # (N-m/m); y-component of buoyant moment per unit length at Tw node 1; local tower coordinate system
AeroDyn['TwN2Mby']            = False     # (N-m/m); y-component of buoyant moment per unit length at Tw node 2; local tower coordinate system
AeroDyn['TwN3Mby']            = False     # (N-m/m); y-component of buoyant moment per unit length at Tw node 3; local tower coordinate system
AeroDyn['TwN4Mby']            = False     # (N-m/m); y-component of buoyant moment per unit length at Tw node 4; local tower coordinate system
AeroDyn['TwN5Mby']            = False     # (N-m/m); y-component of buoyant moment per unit length at Tw node 5; local tower coordinate system
AeroDyn['TwN6Mby']            = False     # (N-m/m); y-component of buoyant moment per unit length at Tw node 6; local tower coordinate system
AeroDyn['TwN7Mby']            = False     # (N-m/m); y-component of buoyant moment per unit length at Tw node 7; local tower coordinate system
AeroDyn['TwN8Mby']            = False     # (N-m/m); y-component of buoyant moment per unit length at Tw node 8; local tower coordinate system
AeroDyn['TwN9Mby']            = False     # (N-m/m); y-component of buoyant moment per unit length at Tw node 9; local tower coordinate system
AeroDyn['TwN1Mbz']            = False     # (N-m/m); z-component of buoyant moment per unit length at Tw node 1; local tower coordinate system
AeroDyn['TwN2Mbz']            = False     # (N-m/m); z-component of buoyant moment per unit length at Tw node 2; local tower coordinate system
AeroDyn['TwN3Mbz']            = False     # (N-m/m); z-component of buoyant moment per unit length at Tw node 3; local tower coordinate system
AeroDyn['TwN4Mbz']            = False     # (N-m/m); z-component of buoyant moment per unit length at Tw node 4; local tower coordinate system
AeroDyn['TwN5Mbz']            = False     # (N-m/m); z-component of buoyant moment per unit length at Tw node 5; local tower coordinate system
AeroDyn['TwN6Mbz']            = False     # (N-m/m); z-component of buoyant moment per unit length at Tw node 6; local tower coordinate system
AeroDyn['TwN7Mbz']            = False     # (N-m/m); z-component of buoyant moment per unit length at Tw node 7; local tower coordinate system
AeroDyn['TwN8Mbz']            = False     # (N-m/m); z-component of buoyant moment per unit length at Tw node 8; local tower coordinate system
AeroDyn['TwN9Mbz']            = False     # (N-m/m); z-component of buoyant moment per unit length at Tw node 9; local tower coordinate system

# Blade
AeroDyn['B1Azimuth']          = False     # (deg); Azimuth angle of blade 1; 
AeroDyn['B2Azimuth']          = False     # (deg); Azimuth angle of blade 2; 
AeroDyn['B3Azimuth']          = False     # (deg); Azimuth angle of blade 3; 
AeroDyn['B1Pitch']            = False     # (deg); Pitch angle of blade 1; 
AeroDyn['B2Pitch']            = False     # (deg); Pitch angle of blade 2; 
AeroDyn['B3Pitch']            = False     # (deg); Pitch angle of blade 3; 
AeroDyn['B1AeroFx']           = False     # (N); Total blade aerodynamic/hydrodynamic load for blade 1 (force in x-direction); blade root coordinate system
AeroDyn['B1FldFx']            = False     # (N); Total blade aerodynamic/hydrodynamic load for blade 1 (force in x-direction); blade root coordinate system
AeroDyn['B1AeroFy']           = False     # (N); Total blade aerodynamic/hydrodynamic load for blade 1 (force in y-direction); blade root coordinate system
AeroDyn['B1FldFy']            = False     # (N); Total blade aerodynamic/hydrodynamic load for blade 1 (force in y-direction); blade root coordinate system
AeroDyn['B1AeroFz']           = False     # (N); Total blade aerodynamic/hydrodynamic load for blade 1 (force in z-direction); blade root coordinate system
AeroDyn['B1FldFz']            = False     # (N); Total blade aerodynamic/hydrodynamic load for blade 1 (force in z-direction); blade root coordinate system
AeroDyn['B1AeroMx']           = False     # (N-m); Total blade aerodynamic/hydrodynamic load for blade 1 (moment in x-direction); blade root coordinate system
AeroDyn['B1FldMx']            = False     # (N-m); Total blade aerodynamic/hydrodynamic load for blade 1 (moment in x-direction); blade root coordinate system
AeroDyn['B1AeroMy']           = False     # (N-m); Total blade aerodynamic/hydrodynamic load for blade 1 (moment in y-direction); blade root coordinate system
AeroDyn['B1FldMy']            = False     # (N-m); Total blade aerodynamic/hydrodynamic load for blade 1 (moment in y-direction); blade root coordinate system
AeroDyn['B1AeroMz']           = False     # (N-m); Total blade aerodynamic/hydrodynamic load for blade 1 (moment in z-direction); blade root coordinate system
AeroDyn['B1FldMz']            = False     # (N-m); Total blade aerodynamic/hydrodynamic load for blade 1 (moment in z-direction); blade root coordinate system
AeroDyn['B1AeroPwr']          = False     # (W); Total aerodynamic/hydrodynamic power from blade 1; 
AeroDyn['B1FldPwr']           = False     # (W); Total aerodynamic/hydrodynamic power from blade 1; 
AeroDyn['B2AeroFx']           = False     # (N); Total blade aerodynamic/hydrodynamic load for blade 2 (force in x-direction); blade root coordinate system
AeroDyn['B2FldFx']            = False     # (N); Total blade aerodynamic/hydrodynamic load for blade 2 (force in x-direction); blade root coordinate system
AeroDyn['B2AeroFy']           = False     # (N); Total blade aerodynamic/hydrodynamic load for blade 2 (force in y-direction); blade root coordinate system
AeroDyn['B2FldFy']            = False     # (N); Total blade aerodynamic/hydrodynamic load for blade 2 (force in y-direction); blade root coordinate system
AeroDyn['B2AeroFz']           = False     # (N); Total blade aerodynamic/hydrodynamic load for blade 2 (force in z-direction); blade root coordinate system
AeroDyn['B2FldFz']            = False     # (N); Total blade aerodynamic/hydrodynamic load for blade 2 (force in z-direction); blade root coordinate system
AeroDyn['B2AeroMx']           = False     # (N-m); Total blade aerodynamic/hydrodynamic load for blade 2 (moment in x-direction); blade root coordinate system
AeroDyn['B2FldMx']            = False     # (N-m); Total blade aerodynamic/hydrodynamic load for blade 2 (moment in x-direction); blade root coordinate system
AeroDyn['B2AeroMy']           = False     # (N-m); Total blade aerodynamic/hydrodynamic load for blade 2 (moment in y-direction); blade root coordinate system
AeroDyn['B2FldMy']            = False     # (N-m); Total blade aerodynamic/hydrodynamic load for blade 2 (moment in y-direction); blade root coordinate system
AeroDyn['B2AeroMz']           = False     # (N-m); Total blade aerodynamic/hydrodynamic load for blade 2 (moment in z-direction); blade root coordinate system
AeroDyn['B2FldMz']            = False     # (N-m); Total blade aerodynamic/hydrodynamic load for blade 2 (moment in z-direction); blade root coordinate system
AeroDyn['B2AeroPwr']          = False     # (W); Total aerodynamic/hydrodynamic power from blade 2; 
AeroDyn['B2FldPwr']           = False     # (W); Total aerodynamic/hydrodynamic power from blade 2; 
AeroDyn['B3AeroFx']           = False     # (N); Total blade aerodynamic/hydrodynamic load for blade 3 (force in x-direction); blade root coordinate system
AeroDyn['B3FldFx']            = False     # (N); Total blade aerodynamic/hydrodynamic load for blade 3 (force in x-direction); blade root coordinate system
AeroDyn['B3AeroFy']           = False     # (N); Total blade aerodynamic/hydrodynamic load for blade 3 (force in y-direction); blade root coordinate system
AeroDyn['B3FldFy']            = False     # (N); Total blade aerodynamic/hydrodynamic load for blade 3 (force in y-direction); blade root coordinate system
AeroDyn['B3AeroFz']           = False     # (N); Total blade aerodynamic/hydrodynamic load for blade 3 (force in z-direction); blade root coordinate system
AeroDyn['B3FldFz']            = False     # (N); Total blade aerodynamic/hydrodynamic load for blade 3 (force in z-direction); blade root coordinate system
AeroDyn['B3AeroMx']           = False     # (N-m); Total blade aerodynamic/hydrodynamic load for blade 3 (moment in x-direction); blade root coordinate system
AeroDyn['B3FldMx']            = False     # (N-m); Total blade aerodynamic/hydrodynamic load for blade 3 (moment in x-direction); blade root coordinate system
AeroDyn['B3AeroMy']           = False     # (N-m); Total blade aerodynamic/hydrodynamic load for blade 3 (moment in y-direction); blade root coordinate system
AeroDyn['B3FldMy']            = False     # (N-m); Total blade aerodynamic/hydrodynamic load for blade 3 (moment in y-direction); blade root coordinate system
AeroDyn['B3AeroMz']           = False     # (N-m); Total blade aerodynamic/hydrodynamic load for blade 3 (moment in z-direction); blade root coordinate system
AeroDyn['B3FldMz']            = False     # (N-m); Total blade aerodynamic/hydrodynamic load for blade 3 (moment in z-direction); blade root coordinate system
AeroDyn['B3AeroPwr']          = False     # (W); Total aerodynamic/hydrodynamic power from blade 3; 
AeroDyn['B3FldPwr']           = False     # (W); Total aerodynamic/hydrodynamic power from blade 3; 
AeroDyn['B4AeroFx']           = False     # (N); Total blade aerodynamic/hydrodynamic load for blade 4 (force in x-direction); blade root coordinate system
AeroDyn['B4FldFx']            = False     # (N); Total blade aerodynamic/hydrodynamic load for blade 4 (force in x-direction); blade root coordinate system
AeroDyn['B4AeroFy']           = False     # (N); Total blade aerodynamic/hydrodynamic load for blade 4 (force in y-direction); blade root coordinate system
AeroDyn['B4FldFy']            = False     # (N); Total blade aerodynamic/hydrodynamic load for blade 4 (force in y-direction); blade root coordinate system
AeroDyn['B4AeroFz']           = False     # (N); Total blade aerodynamic/hydrodynamic load for blade 4 (force in z-direction); blade root coordinate system
AeroDyn['B4FldFz']            = False     # (N); Total blade aerodynamic/hydrodynamic load for blade 4 (force in z-direction); blade root coordinate system
AeroDyn['B4AeroMx']           = False     # (N-m); Total blade aerodynamic/hydrodynamic load for blade 4 (moment in x-direction); blade root coordinate system
AeroDyn['B4FldMx']            = False     # (N-m); Total blade aerodynamic/hydrodynamic load for blade 4 (moment in x-direction); blade root coordinate system
AeroDyn['B4AeroMy']           = False     # (N-m); Total blade aerodynamic/hydrodynamic load for blade 4 (moment in y-direction); blade root coordinate system
AeroDyn['B4FldMy']            = False     # (N-m); Total blade aerodynamic/hydrodynamic load for blade 4 (moment in y-direction); blade root coordinate system
AeroDyn['B4AeroMz']           = False     # (N-m); Total blade aerodynamic/hydrodynamic load for blade 4 (moment in z-direction); blade root coordinate system
AeroDyn['B4FldMz']            = False     # (N-m); Total blade aerodynamic/hydrodynamic load for blade 4 (moment in z-direction); blade root coordinate system
AeroDyn['B4AeroPwr']          = False     # (W); Total aerodynamic/hydrodynamic power from blade 4; 
AeroDyn['B4FldPwr']           = False     # (W); Total aerodynamic/hydrodynamic power from blade 4; 
AeroDyn['B1AeroFxi']          = False     # (N); Total blade aerodynamic/hydrodynamic load for blade 1 (force in x-direction); global coordinate system
AeroDyn['B1FldFxi']           = False     # (N); Total blade aerodynamic/hydrodynamic load for blade 1 (force in x-direction); global coordinate system
AeroDyn['B1AeroFyi']          = False     # (N); Total blade aerodynamic/hydrodynamic load for blade 1 (force in y-direction); global coordinate system
AeroDyn['B1FldFyi']           = False     # (N); Total blade aerodynamic/hydrodynamic load for blade 1 (force in y-direction); global coordinate system
AeroDyn['B1AeroFzi']          = False     # (N); Total blade aerodynamic/hydrodynamic load for blade 1 (force in z-direction); global coordinate system
AeroDyn['B1FldFzi']           = False     # (N); Total blade aerodynamic/hydrodynamic load for blade 1 (force in z-direction); global coordinate system
AeroDyn['B1AeroMxi']          = False     # (N-m); Total blade aerodynamic/hydrodynamic load for blade 1 (moment in x-direction); global coordinate system
AeroDyn['B1FldMxi']           = False     # (N-m); Total blade aerodynamic/hydrodynamic load for blade 1 (moment in x-direction); global coordinate system
AeroDyn['B1AeroMyi']          = False     # (N-m); Total blade aerodynamic/hydrodynamic load for blade 1 (moment in y-direction); global coordinate system
AeroDyn['B1FldMyi']           = False     # (N-m); Total blade aerodynamic/hydrodynamic load for blade 1 (moment in y-direction); global coordinate system
AeroDyn['B1AeroMzi']          = False     # (N-m); Total blade aerodynamic/hydrodynamic load for blade 1 (moment in z-direction); global coordinate system
AeroDyn['B1FldMzi']           = False     # (N-m); Total blade aerodynamic/hydrodynamic load for blade 1 (moment in z-direction); global coordinate system
AeroDyn['B2AeroFxi']          = False     # (N); Total blade aerodynamic/hydrodynamic load for blade 2 (force in x-direction); global coordinate system
AeroDyn['B2FldFxi']           = False     # (N); Total blade aerodynamic/hydrodynamic load for blade 2 (force in x-direction); global coordinate system
AeroDyn['B2AeroFyi']          = False     # (N); Total blade aerodynamic/hydrodynamic load for blade 2 (force in y-direction); global coordinate system
AeroDyn['B2FldFyi']           = False     # (N); Total blade aerodynamic/hydrodynamic load for blade 2 (force in y-direction); global coordinate system
AeroDyn['B2AeroFzi']          = False     # (N); Total blade aerodynamic/hydrodynamic load for blade 2 (force in z-direction); global coordinate system
AeroDyn['B2FldFzi']           = False     # (N); Total blade aerodynamic/hydrodynamic load for blade 2 (force in z-direction); global coordinate system
AeroDyn['B2AeroMxi']          = False     # (N-m); Total blade aerodynamic/hydrodynamic load for blade 2 (moment in x-direction); global coordinate system
AeroDyn['B2FldMxi']           = False     # (N-m); Total blade aerodynamic/hydrodynamic load for blade 2 (moment in x-direction); global coordinate system
AeroDyn['B2AeroMyi']          = False     # (N-m); Total blade aerodynamic/hydrodynamic load for blade 2 (moment in y-direction); global coordinate system
AeroDyn['B2FldMyi']           = False     # (N-m); Total blade aerodynamic/hydrodynamic load for blade 2 (moment in y-direction); global coordinate system
AeroDyn['B2AeroMzi']          = False     # (N-m); Total blade aerodynamic/hydrodynamic load for blade 2 (moment in z-direction); global coordinate system
AeroDyn['B2FldMzi']           = False     # (N-m); Total blade aerodynamic/hydrodynamic load for blade 2 (moment in z-direction); global coordinate system
AeroDyn['B3AeroFxi']          = False     # (N); Total blade aerodynamic/hydrodynamic load for blade 3 (force in x-direction); global coordinate system
AeroDyn['B3FldFxi']           = False     # (N); Total blade aerodynamic/hydrodynamic load for blade 3 (force in x-direction); global coordinate system
AeroDyn['B3AeroFyi']          = False     # (N); Total blade aerodynamic/hydrodynamic load for blade 3 (force in y-direction); global coordinate system
AeroDyn['B3FldFyi']           = False     # (N); Total blade aerodynamic/hydrodynamic load for blade 3 (force in y-direction); global coordinate system
AeroDyn['B3AeroFzi']          = False     # (N); Total blade aerodynamic/hydrodynamic load for blade 3 (force in z-direction); global coordinate system
AeroDyn['B3FldFzi']           = False     # (N); Total blade aerodynamic/hydrodynamic load for blade 3 (force in z-direction); global coordinate system
AeroDyn['B3AeroMxi']          = False     # (N-m); Total blade aerodynamic/hydrodynamic load for blade 3 (moment in x-direction); global coordinate system
AeroDyn['B3FldMxi']           = False     # (N-m); Total blade aerodynamic/hydrodynamic load for blade 3 (moment in x-direction); global coordinate system
AeroDyn['B3AeroMyi']          = False     # (N-m); Total blade aerodynamic/hydrodynamic load for blade 3 (moment in y-direction); global coordinate system
AeroDyn['B3FldMyi']           = False     # (N-m); Total blade aerodynamic/hydrodynamic load for blade 3 (moment in y-direction); global coordinate system
AeroDyn['B3AeroMzi']          = False     # (N-m); Total blade aerodynamic/hydrodynamic load for blade 3 (moment in z-direction); global coordinate system
AeroDyn['B3FldMzi']           = False     # (N-m); Total blade aerodynamic/hydrodynamic load for blade 3 (moment in z-direction); global coordinate system
AeroDyn['B4AeroFxi']          = False     # (N); Total blade aerodynamic/hydrodynamic load for blade 4 (force in x-direction); global coordinate system
AeroDyn['B4FldFxi']           = False     # (N); Total blade aerodynamic/hydrodynamic load for blade 4 (force in x-direction); global coordinate system
AeroDyn['B4AeroFyi']          = False     # (N); Total blade aerodynamic/hydrodynamic load for blade 4 (force in y-direction); global coordinate system
AeroDyn['B4FldFyi']           = False     # (N); Total blade aerodynamic/hydrodynamic load for blade 4 (force in y-direction); global coordinate system
AeroDyn['B4AeroFzi']          = False     # (N); Total blade aerodynamic/hydrodynamic load for blade 4 (force in z-direction); global coordinate system
AeroDyn['B4FldFzi']           = False     # (N); Total blade aerodynamic/hydrodynamic load for blade 4 (force in z-direction); global coordinate system
AeroDyn['B4AeroMxi']          = False     # (N-m); Total blade aerodynamic/hydrodynamic load for blade 4 (moment in x-direction); global coordinate system
AeroDyn['B4FldMxi']           = False     # (N-m); Total blade aerodynamic/hydrodynamic load for blade 4 (moment in x-direction); global coordinate system
AeroDyn['B4AeroMyi']          = False     # (N-m); Total blade aerodynamic/hydrodynamic load for blade 4 (moment in y-direction); global coordinate system
AeroDyn['B4FldMyi']           = False     # (N-m); Total blade aerodynamic/hydrodynamic load for blade 4 (moment in y-direction); global coordinate system
AeroDyn['B4AeroMzi']          = False     # (N-m); Total blade aerodynamic/hydrodynamic load for blade 4 (moment in z-direction); global coordinate system
AeroDyn['B4FldMzi']           = False     # (N-m); Total blade aerodynamic/hydrodynamic load for blade 4 (moment in z-direction); global coordinate system

# Blade Nodal outputs
AeroDyn['B1N1VUndx']          = False     # (m/s); x-component of undisturbed wind velocity at Blade 1, Node 1; local blade coordinate system
AeroDyn['B1N2VUndx']          = False     # (m/s); x-component of undisturbed wind velocity at Blade 1, Node 2; local blade coordinate system
AeroDyn['B1N3VUndx']          = False     # (m/s); x-component of undisturbed wind velocity at Blade 1, Node 3; local blade coordinate system
AeroDyn['B1N4VUndx']          = False     # (m/s); x-component of undisturbed wind velocity at Blade 1, Node 4; local blade coordinate system
AeroDyn['B1N5VUndx']          = False     # (m/s); x-component of undisturbed wind velocity at Blade 1, Node 5; local blade coordinate system
AeroDyn['B1N6VUndx']          = False     # (m/s); x-component of undisturbed wind velocity at Blade 1, Node 6; local blade coordinate system
AeroDyn['B1N7VUndx']          = False     # (m/s); x-component of undisturbed wind velocity at Blade 1, Node 7; local blade coordinate system
AeroDyn['B1N8VUndx']          = False     # (m/s); x-component of undisturbed wind velocity at Blade 1, Node 8; local blade coordinate system
AeroDyn['B1N9VUndx']          = False     # (m/s); x-component of undisturbed wind velocity at Blade 1, Node 9; local blade coordinate system
AeroDyn['B1N1VUndy']          = False     # (m/s); y-component of undisturbed wind velocity at Blade 1, Node 1; local blade coordinate system
AeroDyn['B1N2VUndy']          = False     # (m/s); y-component of undisturbed wind velocity at Blade 1, Node 2; local blade coordinate system
AeroDyn['B1N3VUndy']          = False     # (m/s); y-component of undisturbed wind velocity at Blade 1, Node 3; local blade coordinate system
AeroDyn['B1N4VUndy']          = False     # (m/s); y-component of undisturbed wind velocity at Blade 1, Node 4; local blade coordinate system
AeroDyn['B1N5VUndy']          = False     # (m/s); y-component of undisturbed wind velocity at Blade 1, Node 5; local blade coordinate system
AeroDyn['B1N6VUndy']          = False     # (m/s); y-component of undisturbed wind velocity at Blade 1, Node 6; local blade coordinate system
AeroDyn['B1N7VUndy']          = False     # (m/s); y-component of undisturbed wind velocity at Blade 1, Node 7; local blade coordinate system
AeroDyn['B1N8VUndy']          = False     # (m/s); y-component of undisturbed wind velocity at Blade 1, Node 8; local blade coordinate system
AeroDyn['B1N9VUndy']          = False     # (m/s); y-component of undisturbed wind velocity at Blade 1, Node 9; local blade coordinate system
AeroDyn['B1N1VUndz']          = False     # (m/s); z-component of undisturbed wind velocity at Blade 1, Node 1; local blade coordinate system
AeroDyn['B1N2VUndz']          = False     # (m/s); z-component of undisturbed wind velocity at Blade 1, Node 2; local blade coordinate system
AeroDyn['B1N3VUndz']          = False     # (m/s); z-component of undisturbed wind velocity at Blade 1, Node 3; local blade coordinate system
AeroDyn['B1N4VUndz']          = False     # (m/s); z-component of undisturbed wind velocity at Blade 1, Node 4; local blade coordinate system
AeroDyn['B1N5VUndz']          = False     # (m/s); z-component of undisturbed wind velocity at Blade 1, Node 5; local blade coordinate system
AeroDyn['B1N6VUndz']          = False     # (m/s); z-component of undisturbed wind velocity at Blade 1, Node 6; local blade coordinate system
AeroDyn['B1N7VUndz']          = False     # (m/s); z-component of undisturbed wind velocity at Blade 1, Node 7; local blade coordinate system
AeroDyn['B1N8VUndz']          = False     # (m/s); z-component of undisturbed wind velocity at Blade 1, Node 8; local blade coordinate system
AeroDyn['B1N9VUndz']          = False     # (m/s); z-component of undisturbed wind velocity at Blade 1, Node 9; local blade coordinate system
AeroDyn['B2N1VUndx']          = False     # (m/s); x-component of undisturbed wind velocity at Blade 2, Node 1; local blade coordinate system
AeroDyn['B2N2VUndx']          = False     # (m/s); x-component of undisturbed wind velocity at Blade 2, Node 2; local blade coordinate system
AeroDyn['B2N3VUndx']          = False     # (m/s); x-component of undisturbed wind velocity at Blade 2, Node 3; local blade coordinate system
AeroDyn['B2N4VUndx']          = False     # (m/s); x-component of undisturbed wind velocity at Blade 2, Node 4; local blade coordinate system
AeroDyn['B2N5VUndx']          = False     # (m/s); x-component of undisturbed wind velocity at Blade 2, Node 5; local blade coordinate system
AeroDyn['B2N6VUndx']          = False     # (m/s); x-component of undisturbed wind velocity at Blade 2, Node 6; local blade coordinate system
AeroDyn['B2N7VUndx']          = False     # (m/s); x-component of undisturbed wind velocity at Blade 2, Node 7; local blade coordinate system
AeroDyn['B2N8VUndx']          = False     # (m/s); x-component of undisturbed wind velocity at Blade 2, Node 8; local blade coordinate system
AeroDyn['B2N9VUndx']          = False     # (m/s); x-component of undisturbed wind velocity at Blade 2, Node 9; local blade coordinate system
AeroDyn['B2N1VUndy']          = False     # (m/s); y-component of undisturbed wind velocity at Blade 2, Node 1; local blade coordinate system
AeroDyn['B2N2VUndy']          = False     # (m/s); y-component of undisturbed wind velocity at Blade 2, Node 2; local blade coordinate system
AeroDyn['B2N3VUndy']          = False     # (m/s); y-component of undisturbed wind velocity at Blade 2, Node 3; local blade coordinate system
AeroDyn['B2N4VUndy']          = False     # (m/s); y-component of undisturbed wind velocity at Blade 2, Node 4; local blade coordinate system
AeroDyn['B2N5VUndy']          = False     # (m/s); y-component of undisturbed wind velocity at Blade 2, Node 5; local blade coordinate system
AeroDyn['B2N6VUndy']          = False     # (m/s); y-component of undisturbed wind velocity at Blade 2, Node 6; local blade coordinate system
AeroDyn['B2N7VUndy']          = False     # (m/s); y-component of undisturbed wind velocity at Blade 2, Node 7; local blade coordinate system
AeroDyn['B2N8VUndy']          = False     # (m/s); y-component of undisturbed wind velocity at Blade 2, Node 8; local blade coordinate system
AeroDyn['B2N9VUndy']          = False     # (m/s); y-component of undisturbed wind velocity at Blade 2, Node 9; local blade coordinate system
AeroDyn['B2N1VUndz']          = False     # (m/s); z-component of undisturbed wind velocity at Blade 2, Node 1; local blade coordinate system
AeroDyn['B2N2VUndz']          = False     # (m/s); z-component of undisturbed wind velocity at Blade 2, Node 2; local blade coordinate system
AeroDyn['B2N3VUndz']          = False     # (m/s); z-component of undisturbed wind velocity at Blade 2, Node 3; local blade coordinate system
AeroDyn['B2N4VUndz']          = False     # (m/s); z-component of undisturbed wind velocity at Blade 2, Node 4; local blade coordinate system
AeroDyn['B2N5VUndz']          = False     # (m/s); z-component of undisturbed wind velocity at Blade 2, Node 5; local blade coordinate system
AeroDyn['B2N6VUndz']          = False     # (m/s); z-component of undisturbed wind velocity at Blade 2, Node 6; local blade coordinate system
AeroDyn['B2N7VUndz']          = False     # (m/s); z-component of undisturbed wind velocity at Blade 2, Node 7; local blade coordinate system
AeroDyn['B2N8VUndz']          = False     # (m/s); z-component of undisturbed wind velocity at Blade 2, Node 8; local blade coordinate system
AeroDyn['B2N9VUndz']          = False     # (m/s); z-component of undisturbed wind velocity at Blade 2, Node 9; local blade coordinate system
AeroDyn['B3N1VUndx']          = False     # (m/s); x-component of undisturbed wind velocity at Blade 3, Node 1; local blade coordinate system
AeroDyn['B3N2VUndx']          = False     # (m/s); x-component of undisturbed wind velocity at Blade 3, Node 2; local blade coordinate system
AeroDyn['B3N3VUndx']          = False     # (m/s); x-component of undisturbed wind velocity at Blade 3, Node 3; local blade coordinate system
AeroDyn['B3N4VUndx']          = False     # (m/s); x-component of undisturbed wind velocity at Blade 3, Node 4; local blade coordinate system
AeroDyn['B3N5VUndx']          = False     # (m/s); x-component of undisturbed wind velocity at Blade 3, Node 5; local blade coordinate system
AeroDyn['B3N6VUndx']          = False     # (m/s); x-component of undisturbed wind velocity at Blade 3, Node 6; local blade coordinate system
AeroDyn['B3N7VUndx']          = False     # (m/s); x-component of undisturbed wind velocity at Blade 3, Node 7; local blade coordinate system
AeroDyn['B3N8VUndx']          = False     # (m/s); x-component of undisturbed wind velocity at Blade 3, Node 8; local blade coordinate system
AeroDyn['B3N9VUndx']          = False     # (m/s); x-component of undisturbed wind velocity at Blade 3, Node 9; local blade coordinate system
AeroDyn['B3N1VUndy']          = False     # (m/s); y-component of undisturbed wind velocity at Blade 3, Node 1; local blade coordinate system
AeroDyn['B3N2VUndy']          = False     # (m/s); y-component of undisturbed wind velocity at Blade 3, Node 2; local blade coordinate system
AeroDyn['B3N3VUndy']          = False     # (m/s); y-component of undisturbed wind velocity at Blade 3, Node 3; local blade coordinate system
AeroDyn['B3N4VUndy']          = False     # (m/s); y-component of undisturbed wind velocity at Blade 3, Node 4; local blade coordinate system
AeroDyn['B3N5VUndy']          = False     # (m/s); y-component of undisturbed wind velocity at Blade 3, Node 5; local blade coordinate system
AeroDyn['B3N6VUndy']          = False     # (m/s); y-component of undisturbed wind velocity at Blade 3, Node 6; local blade coordinate system
AeroDyn['B3N7VUndy']          = False     # (m/s); y-component of undisturbed wind velocity at Blade 3, Node 7; local blade coordinate system
AeroDyn['B3N8VUndy']          = False     # (m/s); y-component of undisturbed wind velocity at Blade 3, Node 8; local blade coordinate system
AeroDyn['B3N9VUndy']          = False     # (m/s); y-component of undisturbed wind velocity at Blade 3, Node 9; local blade coordinate system
AeroDyn['B3N1VUndz']          = False     # (m/s); z-component of undisturbed wind velocity at Blade 3, Node 1; local blade coordinate system
AeroDyn['B3N2VUndz']          = False     # (m/s); z-component of undisturbed wind velocity at Blade 3, Node 2; local blade coordinate system
AeroDyn['B3N3VUndz']          = False     # (m/s); z-component of undisturbed wind velocity at Blade 3, Node 3; local blade coordinate system
AeroDyn['B3N4VUndz']          = False     # (m/s); z-component of undisturbed wind velocity at Blade 3, Node 4; local blade coordinate system
AeroDyn['B3N5VUndz']          = False     # (m/s); z-component of undisturbed wind velocity at Blade 3, Node 5; local blade coordinate system
AeroDyn['B3N6VUndz']          = False     # (m/s); z-component of undisturbed wind velocity at Blade 3, Node 6; local blade coordinate system
AeroDyn['B3N7VUndz']          = False     # (m/s); z-component of undisturbed wind velocity at Blade 3, Node 7; local blade coordinate system
AeroDyn['B3N8VUndz']          = False     # (m/s); z-component of undisturbed wind velocity at Blade 3, Node 8; local blade coordinate system
AeroDyn['B3N9VUndz']          = False     # (m/s); z-component of undisturbed wind velocity at Blade 3, Node 9; local blade coordinate system
AeroDyn['B1N1VDisx']          = False     # (m/s); x-component of disturbed wind velocity at Blade 1, Node 1; local blade coordinate system
AeroDyn['B1N2VDisx']          = False     # (m/s); x-component of disturbed wind velocity at Blade 1, Node 2; local blade coordinate system
AeroDyn['B1N3VDisx']          = False     # (m/s); x-component of disturbed wind velocity at Blade 1, Node 3; local blade coordinate system
AeroDyn['B1N4VDisx']          = False     # (m/s); x-component of disturbed wind velocity at Blade 1, Node 4; local blade coordinate system
AeroDyn['B1N5VDisx']          = False     # (m/s); x-component of disturbed wind velocity at Blade 1, Node 5; local blade coordinate system
AeroDyn['B1N6VDisx']          = False     # (m/s); x-component of disturbed wind velocity at Blade 1, Node 6; local blade coordinate system
AeroDyn['B1N7VDisx']          = False     # (m/s); x-component of disturbed wind velocity at Blade 1, Node 7; local blade coordinate system
AeroDyn['B1N8VDisx']          = False     # (m/s); x-component of disturbed wind velocity at Blade 1, Node 8; local blade coordinate system
AeroDyn['B1N9VDisx']          = False     # (m/s); x-component of disturbed wind velocity at Blade 1, Node 9; local blade coordinate system
AeroDyn['B1N1VDisy']          = False     # (m/s); y-component of disturbed wind velocity at Blade 1, Node 1; local blade coordinate system
AeroDyn['B1N2VDisy']          = False     # (m/s); y-component of disturbed wind velocity at Blade 1, Node 2; local blade coordinate system
AeroDyn['B1N3VDisy']          = False     # (m/s); y-component of disturbed wind velocity at Blade 1, Node 3; local blade coordinate system
AeroDyn['B1N4VDisy']          = False     # (m/s); y-component of disturbed wind velocity at Blade 1, Node 4; local blade coordinate system
AeroDyn['B1N5VDisy']          = False     # (m/s); y-component of disturbed wind velocity at Blade 1, Node 5; local blade coordinate system
AeroDyn['B1N6VDisy']          = False     # (m/s); y-component of disturbed wind velocity at Blade 1, Node 6; local blade coordinate system
AeroDyn['B1N7VDisy']          = False     # (m/s); y-component of disturbed wind velocity at Blade 1, Node 7; local blade coordinate system
AeroDyn['B1N8VDisy']          = False     # (m/s); y-component of disturbed wind velocity at Blade 1, Node 8; local blade coordinate system
AeroDyn['B1N9VDisy']          = False     # (m/s); y-component of disturbed wind velocity at Blade 1, Node 9; local blade coordinate system
AeroDyn['B1N1VDisz']          = False     # (m/s); z-component of disturbed wind velocity at Blade 1, Node 1; local blade coordinate system
AeroDyn['B1N2VDisz']          = False     # (m/s); z-component of disturbed wind velocity at Blade 1, Node 2; local blade coordinate system
AeroDyn['B1N3VDisz']          = False     # (m/s); z-component of disturbed wind velocity at Blade 1, Node 3; local blade coordinate system
AeroDyn['B1N4VDisz']          = False     # (m/s); z-component of disturbed wind velocity at Blade 1, Node 4; local blade coordinate system
AeroDyn['B1N5VDisz']          = False     # (m/s); z-component of disturbed wind velocity at Blade 1, Node 5; local blade coordinate system
AeroDyn['B1N6VDisz']          = False     # (m/s); z-component of disturbed wind velocity at Blade 1, Node 6; local blade coordinate system
AeroDyn['B1N7VDisz']          = False     # (m/s); z-component of disturbed wind velocity at Blade 1, Node 7; local blade coordinate system
AeroDyn['B1N8VDisz']          = False     # (m/s); z-component of disturbed wind velocity at Blade 1, Node 8; local blade coordinate system
AeroDyn['B1N9VDisz']          = False     # (m/s); z-component of disturbed wind velocity at Blade 1, Node 9; local blade coordinate system
AeroDyn['B2N1VDisx']          = False     # (m/s); x-component of disturbed wind velocity at Blade 2, Node 1; local blade coordinate system
AeroDyn['B2N2VDisx']          = False     # (m/s); x-component of disturbed wind velocity at Blade 2, Node 2; local blade coordinate system
AeroDyn['B2N3VDisx']          = False     # (m/s); x-component of disturbed wind velocity at Blade 2, Node 3; local blade coordinate system
AeroDyn['B2N4VDisx']          = False     # (m/s); x-component of disturbed wind velocity at Blade 2, Node 4; local blade coordinate system
AeroDyn['B2N5VDisx']          = False     # (m/s); x-component of disturbed wind velocity at Blade 2, Node 5; local blade coordinate system
AeroDyn['B2N6VDisx']          = False     # (m/s); x-component of disturbed wind velocity at Blade 2, Node 6; local blade coordinate system
AeroDyn['B2N7VDisx']          = False     # (m/s); x-component of disturbed wind velocity at Blade 2, Node 7; local blade coordinate system
AeroDyn['B2N8VDisx']          = False     # (m/s); x-component of disturbed wind velocity at Blade 2, Node 8; local blade coordinate system
AeroDyn['B2N9VDisx']          = False     # (m/s); x-component of disturbed wind velocity at Blade 2, Node 9; local blade coordinate system
AeroDyn['B2N1VDisy']          = False     # (m/s); y-component of disturbed wind velocity at Blade 2, Node 1; local blade coordinate system
AeroDyn['B2N2VDisy']          = False     # (m/s); y-component of disturbed wind velocity at Blade 2, Node 2; local blade coordinate system
AeroDyn['B2N3VDisy']          = False     # (m/s); y-component of disturbed wind velocity at Blade 2, Node 3; local blade coordinate system
AeroDyn['B2N4VDisy']          = False     # (m/s); y-component of disturbed wind velocity at Blade 2, Node 4; local blade coordinate system
AeroDyn['B2N5VDisy']          = False     # (m/s); y-component of disturbed wind velocity at Blade 2, Node 5; local blade coordinate system
AeroDyn['B2N6VDisy']          = False     # (m/s); y-component of disturbed wind velocity at Blade 2, Node 6; local blade coordinate system
AeroDyn['B2N7VDisy']          = False     # (m/s); y-component of disturbed wind velocity at Blade 2, Node 7; local blade coordinate system
AeroDyn['B2N8VDisy']          = False     # (m/s); y-component of disturbed wind velocity at Blade 2, Node 8; local blade coordinate system
AeroDyn['B2N9VDisy']          = False     # (m/s); y-component of disturbed wind velocity at Blade 2, Node 9; local blade coordinate system
AeroDyn['B2N1VDisz']          = False     # (m/s); z-component of disturbed wind velocity at Blade 2, Node 1; local blade coordinate system
AeroDyn['B2N2VDisz']          = False     # (m/s); z-component of disturbed wind velocity at Blade 2, Node 2; local blade coordinate system
AeroDyn['B2N3VDisz']          = False     # (m/s); z-component of disturbed wind velocity at Blade 2, Node 3; local blade coordinate system
AeroDyn['B2N4VDisz']          = False     # (m/s); z-component of disturbed wind velocity at Blade 2, Node 4; local blade coordinate system
AeroDyn['B2N5VDisz']          = False     # (m/s); z-component of disturbed wind velocity at Blade 2, Node 5; local blade coordinate system
AeroDyn['B2N6VDisz']          = False     # (m/s); z-component of disturbed wind velocity at Blade 2, Node 6; local blade coordinate system
AeroDyn['B2N7VDisz']          = False     # (m/s); z-component of disturbed wind velocity at Blade 2, Node 7; local blade coordinate system
AeroDyn['B2N8VDisz']          = False     # (m/s); z-component of disturbed wind velocity at Blade 2, Node 8; local blade coordinate system
AeroDyn['B2N9VDisz']          = False     # (m/s); z-component of disturbed wind velocity at Blade 2, Node 9; local blade coordinate system
AeroDyn['B3N1VDisx']          = False     # (m/s); x-component of disturbed wind velocity at Blade 3, Node 1; local blade coordinate system
AeroDyn['B3N2VDisx']          = False     # (m/s); x-component of disturbed wind velocity at Blade 3, Node 2; local blade coordinate system
AeroDyn['B3N3VDisx']          = False     # (m/s); x-component of disturbed wind velocity at Blade 3, Node 3; local blade coordinate system
AeroDyn['B3N4VDisx']          = False     # (m/s); x-component of disturbed wind velocity at Blade 3, Node 4; local blade coordinate system
AeroDyn['B3N5VDisx']          = False     # (m/s); x-component of disturbed wind velocity at Blade 3, Node 5; local blade coordinate system
AeroDyn['B3N6VDisx']          = False     # (m/s); x-component of disturbed wind velocity at Blade 3, Node 6; local blade coordinate system
AeroDyn['B3N7VDisx']          = False     # (m/s); x-component of disturbed wind velocity at Blade 3, Node 7; local blade coordinate system
AeroDyn['B3N8VDisx']          = False     # (m/s); x-component of disturbed wind velocity at Blade 3, Node 8; local blade coordinate system
AeroDyn['B3N9VDisx']          = False     # (m/s); x-component of disturbed wind velocity at Blade 3, Node 9; local blade coordinate system
AeroDyn['B3N1VDisy']          = False     # (m/s); y-component of disturbed wind velocity at Blade 3, Node 1; local blade coordinate system
AeroDyn['B3N2VDisy']          = False     # (m/s); y-component of disturbed wind velocity at Blade 3, Node 2; local blade coordinate system
AeroDyn['B3N3VDisy']          = False     # (m/s); y-component of disturbed wind velocity at Blade 3, Node 3; local blade coordinate system
AeroDyn['B3N4VDisy']          = False     # (m/s); y-component of disturbed wind velocity at Blade 3, Node 4; local blade coordinate system
AeroDyn['B3N5VDisy']          = False     # (m/s); y-component of disturbed wind velocity at Blade 3, Node 5; local blade coordinate system
AeroDyn['B3N6VDisy']          = False     # (m/s); y-component of disturbed wind velocity at Blade 3, Node 6; local blade coordinate system
AeroDyn['B3N7VDisy']          = False     # (m/s); y-component of disturbed wind velocity at Blade 3, Node 7; local blade coordinate system
AeroDyn['B3N8VDisy']          = False     # (m/s); y-component of disturbed wind velocity at Blade 3, Node 8; local blade coordinate system
AeroDyn['B3N9VDisy']          = False     # (m/s); y-component of disturbed wind velocity at Blade 3, Node 9; local blade coordinate system
AeroDyn['B3N1VDisz']          = False     # (m/s); z-component of disturbed wind velocity at Blade 3, Node 1; local blade coordinate system
AeroDyn['B3N2VDisz']          = False     # (m/s); z-component of disturbed wind velocity at Blade 3, Node 2; local blade coordinate system
AeroDyn['B3N3VDisz']          = False     # (m/s); z-component of disturbed wind velocity at Blade 3, Node 3; local blade coordinate system
AeroDyn['B3N4VDisz']          = False     # (m/s); z-component of disturbed wind velocity at Blade 3, Node 4; local blade coordinate system
AeroDyn['B3N5VDisz']          = False     # (m/s); z-component of disturbed wind velocity at Blade 3, Node 5; local blade coordinate system
AeroDyn['B3N6VDisz']          = False     # (m/s); z-component of disturbed wind velocity at Blade 3, Node 6; local blade coordinate system
AeroDyn['B3N7VDisz']          = False     # (m/s); z-component of disturbed wind velocity at Blade 3, Node 7; local blade coordinate system
AeroDyn['B3N8VDisz']          = False     # (m/s); z-component of disturbed wind velocity at Blade 3, Node 8; local blade coordinate system
AeroDyn['B3N9VDisz']          = False     # (m/s); z-component of disturbed wind velocity at Blade 3, Node 9; local blade coordinate system
AeroDyn['B1N1STVx']           = False     # (m/s); x-component of structural translational velocity at Blade 1, Node 1; local blade coordinate system
AeroDyn['B1N2STVx']           = False     # (m/s); x-component of structural translational velocity at Blade 1, Node 2; local blade coordinate system
AeroDyn['B1N3STVx']           = False     # (m/s); x-component of structural translational velocity at Blade 1, Node 3; local blade coordinate system
AeroDyn['B1N4STVx']           = False     # (m/s); x-component of structural translational velocity at Blade 1, Node 4; local blade coordinate system
AeroDyn['B1N5STVx']           = False     # (m/s); x-component of structural translational velocity at Blade 1, Node 5; local blade coordinate system
AeroDyn['B1N6STVx']           = False     # (m/s); x-component of structural translational velocity at Blade 1, Node 6; local blade coordinate system
AeroDyn['B1N7STVx']           = False     # (m/s); x-component of structural translational velocity at Blade 1, Node 7; local blade coordinate system
AeroDyn['B1N8STVx']           = False     # (m/s); x-component of structural translational velocity at Blade 1, Node 8; local blade coordinate system
AeroDyn['B1N9STVx']           = False     # (m/s); x-component of structural translational velocity at Blade 1, Node 9; local blade coordinate system
AeroDyn['B1N1STVy']           = False     # (m/s); y-component of structural translational velocity at Blade 1, Node 1; local blade coordinate system
AeroDyn['B1N2STVy']           = False     # (m/s); y-component of structural translational velocity at Blade 1, Node 2; local blade coordinate system
AeroDyn['B1N3STVy']           = False     # (m/s); y-component of structural translational velocity at Blade 1, Node 3; local blade coordinate system
AeroDyn['B1N4STVy']           = False     # (m/s); y-component of structural translational velocity at Blade 1, Node 4; local blade coordinate system
AeroDyn['B1N5STVy']           = False     # (m/s); y-component of structural translational velocity at Blade 1, Node 5; local blade coordinate system
AeroDyn['B1N6STVy']           = False     # (m/s); y-component of structural translational velocity at Blade 1, Node 6; local blade coordinate system
AeroDyn['B1N7STVy']           = False     # (m/s); y-component of structural translational velocity at Blade 1, Node 7; local blade coordinate system
AeroDyn['B1N8STVy']           = False     # (m/s); y-component of structural translational velocity at Blade 1, Node 8; local blade coordinate system
AeroDyn['B1N9STVy']           = False     # (m/s); y-component of structural translational velocity at Blade 1, Node 9; local blade coordinate system
AeroDyn['B1N1STVz']           = False     # (m/s); z-component of structural translational velocity at Blade 1, Node 1; local blade coordinate system
AeroDyn['B1N2STVz']           = False     # (m/s); z-component of structural translational velocity at Blade 1, Node 2; local blade coordinate system
AeroDyn['B1N3STVz']           = False     # (m/s); z-component of structural translational velocity at Blade 1, Node 3; local blade coordinate system
AeroDyn['B1N4STVz']           = False     # (m/s); z-component of structural translational velocity at Blade 1, Node 4; local blade coordinate system
AeroDyn['B1N5STVz']           = False     # (m/s); z-component of structural translational velocity at Blade 1, Node 5; local blade coordinate system
AeroDyn['B1N6STVz']           = False     # (m/s); z-component of structural translational velocity at Blade 1, Node 6; local blade coordinate system
AeroDyn['B1N7STVz']           = False     # (m/s); z-component of structural translational velocity at Blade 1, Node 7; local blade coordinate system
AeroDyn['B1N8STVz']           = False     # (m/s); z-component of structural translational velocity at Blade 1, Node 8; local blade coordinate system
AeroDyn['B1N9STVz']           = False     # (m/s); z-component of structural translational velocity at Blade 1, Node 9; local blade coordinate system
AeroDyn['B2N1STVx']           = False     # (m/s); x-component of structural translational velocity at Blade 2, Node 1; local blade coordinate system
AeroDyn['B2N2STVx']           = False     # (m/s); x-component of structural translational velocity at Blade 2, Node 2; local blade coordinate system
AeroDyn['B2N3STVx']           = False     # (m/s); x-component of structural translational velocity at Blade 2, Node 3; local blade coordinate system
AeroDyn['B2N4STVx']           = False     # (m/s); x-component of structural translational velocity at Blade 2, Node 4; local blade coordinate system
AeroDyn['B2N5STVx']           = False     # (m/s); x-component of structural translational velocity at Blade 2, Node 5; local blade coordinate system
AeroDyn['B2N6STVx']           = False     # (m/s); x-component of structural translational velocity at Blade 2, Node 6; local blade coordinate system
AeroDyn['B2N7STVx']           = False     # (m/s); x-component of structural translational velocity at Blade 2, Node 7; local blade coordinate system
AeroDyn['B2N8STVx']           = False     # (m/s); x-component of structural translational velocity at Blade 2, Node 8; local blade coordinate system
AeroDyn['B2N9STVx']           = False     # (m/s); x-component of structural translational velocity at Blade 2, Node 9; local blade coordinate system
AeroDyn['B2N1STVy']           = False     # (m/s); y-component of structural translational velocity at Blade 2, Node 1; local blade coordinate system
AeroDyn['B2N2STVy']           = False     # (m/s); y-component of structural translational velocity at Blade 2, Node 2; local blade coordinate system
AeroDyn['B2N3STVy']           = False     # (m/s); y-component of structural translational velocity at Blade 2, Node 3; local blade coordinate system
AeroDyn['B2N4STVy']           = False     # (m/s); y-component of structural translational velocity at Blade 2, Node 4; local blade coordinate system
AeroDyn['B2N5STVy']           = False     # (m/s); y-component of structural translational velocity at Blade 2, Node 5; local blade coordinate system
AeroDyn['B2N6STVy']           = False     # (m/s); y-component of structural translational velocity at Blade 2, Node 6; local blade coordinate system
AeroDyn['B2N7STVy']           = False     # (m/s); y-component of structural translational velocity at Blade 2, Node 7; local blade coordinate system
AeroDyn['B2N8STVy']           = False     # (m/s); y-component of structural translational velocity at Blade 2, Node 8; local blade coordinate system
AeroDyn['B2N9STVy']           = False     # (m/s); y-component of structural translational velocity at Blade 2, Node 9; local blade coordinate system
AeroDyn['B2N1STVz']           = False     # (m/s); z-component of structural translational velocity at Blade 2, Node 1; local blade coordinate system
AeroDyn['B2N2STVz']           = False     # (m/s); z-component of structural translational velocity at Blade 2, Node 2; local blade coordinate system
AeroDyn['B2N3STVz']           = False     # (m/s); z-component of structural translational velocity at Blade 2, Node 3; local blade coordinate system
AeroDyn['B2N4STVz']           = False     # (m/s); z-component of structural translational velocity at Blade 2, Node 4; local blade coordinate system
AeroDyn['B2N5STVz']           = False     # (m/s); z-component of structural translational velocity at Blade 2, Node 5; local blade coordinate system
AeroDyn['B2N6STVz']           = False     # (m/s); z-component of structural translational velocity at Blade 2, Node 6; local blade coordinate system
AeroDyn['B2N7STVz']           = False     # (m/s); z-component of structural translational velocity at Blade 2, Node 7; local blade coordinate system
AeroDyn['B2N8STVz']           = False     # (m/s); z-component of structural translational velocity at Blade 2, Node 8; local blade coordinate system
AeroDyn['B2N9STVz']           = False     # (m/s); z-component of structural translational velocity at Blade 2, Node 9; local blade coordinate system
AeroDyn['B3N1STVx']           = False     # (m/s); x-component of structural translational velocity at Blade 3, Node 1; local blade coordinate system
AeroDyn['B3N2STVx']           = False     # (m/s); x-component of structural translational velocity at Blade 3, Node 2; local blade coordinate system
AeroDyn['B3N3STVx']           = False     # (m/s); x-component of structural translational velocity at Blade 3, Node 3; local blade coordinate system
AeroDyn['B3N4STVx']           = False     # (m/s); x-component of structural translational velocity at Blade 3, Node 4; local blade coordinate system
AeroDyn['B3N5STVx']           = False     # (m/s); x-component of structural translational velocity at Blade 3, Node 5; local blade coordinate system
AeroDyn['B3N6STVx']           = False     # (m/s); x-component of structural translational velocity at Blade 3, Node 6; local blade coordinate system
AeroDyn['B3N7STVx']           = False     # (m/s); x-component of structural translational velocity at Blade 3, Node 7; local blade coordinate system
AeroDyn['B3N8STVx']           = False     # (m/s); x-component of structural translational velocity at Blade 3, Node 8; local blade coordinate system
AeroDyn['B3N9STVx']           = False     # (m/s); x-component of structural translational velocity at Blade 3, Node 9; local blade coordinate system
AeroDyn['B3N1STVy']           = False     # (m/s); y-component of structural translational velocity at Blade 3, Node 1; local blade coordinate system
AeroDyn['B3N2STVy']           = False     # (m/s); y-component of structural translational velocity at Blade 3, Node 2; local blade coordinate system
AeroDyn['B3N3STVy']           = False     # (m/s); y-component of structural translational velocity at Blade 3, Node 3; local blade coordinate system
AeroDyn['B3N4STVy']           = False     # (m/s); y-component of structural translational velocity at Blade 3, Node 4; local blade coordinate system
AeroDyn['B3N5STVy']           = False     # (m/s); y-component of structural translational velocity at Blade 3, Node 5; local blade coordinate system
AeroDyn['B3N6STVy']           = False     # (m/s); y-component of structural translational velocity at Blade 3, Node 6; local blade coordinate system
AeroDyn['B3N7STVy']           = False     # (m/s); y-component of structural translational velocity at Blade 3, Node 7; local blade coordinate system
AeroDyn['B3N8STVy']           = False     # (m/s); y-component of structural translational velocity at Blade 3, Node 8; local blade coordinate system
AeroDyn['B3N9STVy']           = False     # (m/s); y-component of structural translational velocity at Blade 3, Node 9; local blade coordinate system
AeroDyn['B3N1STVz']           = False     # (m/s); z-component of structural translational velocity at Blade 3, Node 1; local blade coordinate system
AeroDyn['B3N2STVz']           = False     # (m/s); z-component of structural translational velocity at Blade 3, Node 2; local blade coordinate system
AeroDyn['B3N3STVz']           = False     # (m/s); z-component of structural translational velocity at Blade 3, Node 3; local blade coordinate system
AeroDyn['B3N4STVz']           = False     # (m/s); z-component of structural translational velocity at Blade 3, Node 4; local blade coordinate system
AeroDyn['B3N5STVz']           = False     # (m/s); z-component of structural translational velocity at Blade 3, Node 5; local blade coordinate system
AeroDyn['B3N6STVz']           = False     # (m/s); z-component of structural translational velocity at Blade 3, Node 6; local blade coordinate system
AeroDyn['B3N7STVz']           = False     # (m/s); z-component of structural translational velocity at Blade 3, Node 7; local blade coordinate system
AeroDyn['B3N8STVz']           = False     # (m/s); z-component of structural translational velocity at Blade 3, Node 8; local blade coordinate system
AeroDyn['B3N9STVz']           = False     # (m/s); z-component of structural translational velocity at Blade 3, Node 9; local blade coordinate system
AeroDyn['B1N1VRel']           = False     # (m/s); Relvative wind speed at Blade 1, Node 1; 
AeroDyn['B1N2VRel']           = False     # (m/s); Relvative wind speed at Blade 1, Node 2; 
AeroDyn['B1N3VRel']           = False     # (m/s); Relvative wind speed at Blade 1, Node 3; 
AeroDyn['B1N4VRel']           = False     # (m/s); Relvative wind speed at Blade 1, Node 4; 
AeroDyn['B1N5VRel']           = False     # (m/s); Relvative wind speed at Blade 1, Node 5; 
AeroDyn['B1N6VRel']           = False     # (m/s); Relvative wind speed at Blade 1, Node 6; 
AeroDyn['B1N7VRel']           = False     # (m/s); Relvative wind speed at Blade 1, Node 7; 
AeroDyn['B1N8VRel']           = False     # (m/s); Relvative wind speed at Blade 1, Node 8; 
AeroDyn['B1N9VRel']           = False     # (m/s); Relvative wind speed at Blade 1, Node 9; 
AeroDyn['B2N1VRel']           = False     # (m/s); Relvative wind speed at Blade 2, Node 1; 
AeroDyn['B2N2VRel']           = False     # (m/s); Relvative wind speed at Blade 2, Node 2; 
AeroDyn['B2N3VRel']           = False     # (m/s); Relvative wind speed at Blade 2, Node 3; 
AeroDyn['B2N4VRel']           = False     # (m/s); Relvative wind speed at Blade 2, Node 4; 
AeroDyn['B2N5VRel']           = False     # (m/s); Relvative wind speed at Blade 2, Node 5; 
AeroDyn['B2N6VRel']           = False     # (m/s); Relvative wind speed at Blade 2, Node 6; 
AeroDyn['B2N7VRel']           = False     # (m/s); Relvative wind speed at Blade 2, Node 7; 
AeroDyn['B2N8VRel']           = False     # (m/s); Relvative wind speed at Blade 2, Node 8; 
AeroDyn['B2N9VRel']           = False     # (m/s); Relvative wind speed at Blade 2, Node 9; 
AeroDyn['B3N1VRel']           = False     # (m/s); Relvative wind speed at Blade 3, Node 1; 
AeroDyn['B3N2VRel']           = False     # (m/s); Relvative wind speed at Blade 3, Node 2; 
AeroDyn['B3N3VRel']           = False     # (m/s); Relvative wind speed at Blade 3, Node 3; 
AeroDyn['B3N4VRel']           = False     # (m/s); Relvative wind speed at Blade 3, Node 4; 
AeroDyn['B3N5VRel']           = False     # (m/s); Relvative wind speed at Blade 3, Node 5; 
AeroDyn['B3N6VRel']           = False     # (m/s); Relvative wind speed at Blade 3, Node 6; 
AeroDyn['B3N7VRel']           = False     # (m/s); Relvative wind speed at Blade 3, Node 7; 
AeroDyn['B3N8VRel']           = False     # (m/s); Relvative wind speed at Blade 3, Node 8; 
AeroDyn['B3N9VRel']           = False     # (m/s); Relvative wind speed at Blade 3, Node 9; 
AeroDyn['B1N1DynP']           = False     # (Pa); Dynamic pressure at Blade 1, Node 1; 
AeroDyn['B1N2DynP']           = False     # (Pa); Dynamic pressure at Blade 1, Node 2; 
AeroDyn['B1N3DynP']           = False     # (Pa); Dynamic pressure at Blade 1, Node 3; 
AeroDyn['B1N4DynP']           = False     # (Pa); Dynamic pressure at Blade 1, Node 4; 
AeroDyn['B1N5DynP']           = False     # (Pa); Dynamic pressure at Blade 1, Node 5; 
AeroDyn['B1N6DynP']           = False     # (Pa); Dynamic pressure at Blade 1, Node 6; 
AeroDyn['B1N7DynP']           = False     # (Pa); Dynamic pressure at Blade 1, Node 7; 
AeroDyn['B1N8DynP']           = False     # (Pa); Dynamic pressure at Blade 1, Node 8; 
AeroDyn['B1N9DynP']           = False     # (Pa); Dynamic pressure at Blade 1, Node 9; 
AeroDyn['B2N1DynP']           = False     # (Pa); Dynamic pressure at Blade 2, Node 1; 
AeroDyn['B2N2DynP']           = False     # (Pa); Dynamic pressure at Blade 2, Node 2; 
AeroDyn['B2N3DynP']           = False     # (Pa); Dynamic pressure at Blade 2, Node 3; 
AeroDyn['B2N4DynP']           = False     # (Pa); Dynamic pressure at Blade 2, Node 4; 
AeroDyn['B2N5DynP']           = False     # (Pa); Dynamic pressure at Blade 2, Node 5; 
AeroDyn['B2N6DynP']           = False     # (Pa); Dynamic pressure at Blade 2, Node 6; 
AeroDyn['B2N7DynP']           = False     # (Pa); Dynamic pressure at Blade 2, Node 7; 
AeroDyn['B2N8DynP']           = False     # (Pa); Dynamic pressure at Blade 2, Node 8; 
AeroDyn['B2N9DynP']           = False     # (Pa); Dynamic pressure at Blade 2, Node 9; 
AeroDyn['B3N1DynP']           = False     # (Pa); Dynamic pressure at Blade 3, Node 1; 
AeroDyn['B3N2DynP']           = False     # (Pa); Dynamic pressure at Blade 3, Node 2; 
AeroDyn['B3N3DynP']           = False     # (Pa); Dynamic pressure at Blade 3, Node 3; 
AeroDyn['B3N4DynP']           = False     # (Pa); Dynamic pressure at Blade 3, Node 4; 
AeroDyn['B3N5DynP']           = False     # (Pa); Dynamic pressure at Blade 3, Node 5; 
AeroDyn['B3N6DynP']           = False     # (Pa); Dynamic pressure at Blade 3, Node 6; 
AeroDyn['B3N7DynP']           = False     # (Pa); Dynamic pressure at Blade 3, Node 7; 
AeroDyn['B3N8DynP']           = False     # (Pa); Dynamic pressure at Blade 3, Node 8; 
AeroDyn['B3N9DynP']           = False     # (Pa); Dynamic pressure at Blade 3, Node 9; 
AeroDyn['B1N1Re']             = False     # (-); Reynolds number (in millions) at Blade 1, Node 1; 
AeroDyn['B1N2Re']             = False     # (-); Reynolds number (in millions) at Blade 1, Node 2; 
AeroDyn['B1N3Re']             = False     # (-); Reynolds number (in millions) at Blade 1, Node 3; 
AeroDyn['B1N4Re']             = False     # (-); Reynolds number (in millions) at Blade 1, Node 4; 
AeroDyn['B1N5Re']             = False     # (-); Reynolds number (in millions) at Blade 1, Node 5; 
AeroDyn['B1N6Re']             = False     # (-); Reynolds number (in millions) at Blade 1, Node 6; 
AeroDyn['B1N7Re']             = False     # (-); Reynolds number (in millions) at Blade 1, Node 7; 
AeroDyn['B1N8Re']             = False     # (-); Reynolds number (in millions) at Blade 1, Node 8; 
AeroDyn['B1N9Re']             = False     # (-); Reynolds number (in millions) at Blade 1, Node 9; 
AeroDyn['B2N1Re']             = False     # (-); Reynolds number (in millions) at Blade 2, Node 1; 
AeroDyn['B2N2Re']             = False     # (-); Reynolds number (in millions) at Blade 2, Node 2; 
AeroDyn['B2N3Re']             = False     # (-); Reynolds number (in millions) at Blade 2, Node 3; 
AeroDyn['B2N4Re']             = False     # (-); Reynolds number (in millions) at Blade 2, Node 4; 
AeroDyn['B2N5Re']             = False     # (-); Reynolds number (in millions) at Blade 2, Node 5; 
AeroDyn['B2N6Re']             = False     # (-); Reynolds number (in millions) at Blade 2, Node 6; 
AeroDyn['B2N7Re']             = False     # (-); Reynolds number (in millions) at Blade 2, Node 7; 
AeroDyn['B2N8Re']             = False     # (-); Reynolds number (in millions) at Blade 2, Node 8; 
AeroDyn['B2N9Re']             = False     # (-); Reynolds number (in millions) at Blade 2, Node 9; 
AeroDyn['B3N1Re']             = False     # (-); Reynolds number (in millions) at Blade 3, Node 1; 
AeroDyn['B3N2Re']             = False     # (-); Reynolds number (in millions) at Blade 3, Node 2; 
AeroDyn['B3N3Re']             = False     # (-); Reynolds number (in millions) at Blade 3, Node 3; 
AeroDyn['B3N4Re']             = False     # (-); Reynolds number (in millions) at Blade 3, Node 4; 
AeroDyn['B3N5Re']             = False     # (-); Reynolds number (in millions) at Blade 3, Node 5; 
AeroDyn['B3N6Re']             = False     # (-); Reynolds number (in millions) at Blade 3, Node 6; 
AeroDyn['B3N7Re']             = False     # (-); Reynolds number (in millions) at Blade 3, Node 7; 
AeroDyn['B3N8Re']             = False     # (-); Reynolds number (in millions) at Blade 3, Node 8; 
AeroDyn['B3N9Re']             = False     # (-); Reynolds number (in millions) at Blade 3, Node 9; 
AeroDyn['B1N1M']              = False     # (-); Mach number at Blade 1, Node 1; 
AeroDyn['B1N2M']              = False     # (-); Mach number at Blade 1, Node 2; 
AeroDyn['B1N3M']              = False     # (-); Mach number at Blade 1, Node 3; 
AeroDyn['B1N4M']              = False     # (-); Mach number at Blade 1, Node 4; 
AeroDyn['B1N5M']              = False     # (-); Mach number at Blade 1, Node 5; 
AeroDyn['B1N6M']              = False     # (-); Mach number at Blade 1, Node 6; 
AeroDyn['B1N7M']              = False     # (-); Mach number at Blade 1, Node 7; 
AeroDyn['B1N8M']              = False     # (-); Mach number at Blade 1, Node 8; 
AeroDyn['B1N9M']              = False     # (-); Mach number at Blade 1, Node 9; 
AeroDyn['B2N1M']              = False     # (-); Mach number at Blade 2, Node 1; 
AeroDyn['B2N2M']              = False     # (-); Mach number at Blade 2, Node 2; 
AeroDyn['B2N3M']              = False     # (-); Mach number at Blade 2, Node 3; 
AeroDyn['B2N4M']              = False     # (-); Mach number at Blade 2, Node 4; 
AeroDyn['B2N5M']              = False     # (-); Mach number at Blade 2, Node 5; 
AeroDyn['B2N6M']              = False     # (-); Mach number at Blade 2, Node 6; 
AeroDyn['B2N7M']              = False     # (-); Mach number at Blade 2, Node 7; 
AeroDyn['B2N8M']              = False     # (-); Mach number at Blade 2, Node 8; 
AeroDyn['B2N9M']              = False     # (-); Mach number at Blade 2, Node 9; 
AeroDyn['B3N1M']              = False     # (-); Mach number at Blade 3, Node 1; 
AeroDyn['B3N2M']              = False     # (-); Mach number at Blade 3, Node 2; 
AeroDyn['B3N3M']              = False     # (-); Mach number at Blade 3, Node 3; 
AeroDyn['B3N4M']              = False     # (-); Mach number at Blade 3, Node 4; 
AeroDyn['B3N5M']              = False     # (-); Mach number at Blade 3, Node 5; 
AeroDyn['B3N6M']              = False     # (-); Mach number at Blade 3, Node 6; 
AeroDyn['B3N7M']              = False     # (-); Mach number at Blade 3, Node 7; 
AeroDyn['B3N8M']              = False     # (-); Mach number at Blade 3, Node 8; 
AeroDyn['B3N9M']              = False     # (-); Mach number at Blade 3, Node 9; 
AeroDyn['B1N1Vindx']          = False     # (m/s); Axial induced wind velocity at Blade 1, Node 1; 
AeroDyn['B1N2Vindx']          = False     # (m/s); Axial induced wind velocity at Blade 1, Node 2; 
AeroDyn['B1N3Vindx']          = False     # (m/s); Axial induced wind velocity at Blade 1, Node 3; 
AeroDyn['B1N4Vindx']          = False     # (m/s); Axial induced wind velocity at Blade 1, Node 4; 
AeroDyn['B1N5Vindx']          = False     # (m/s); Axial induced wind velocity at Blade 1, Node 5; 
AeroDyn['B1N6Vindx']          = False     # (m/s); Axial induced wind velocity at Blade 1, Node 6; 
AeroDyn['B1N7Vindx']          = False     # (m/s); Axial induced wind velocity at Blade 1, Node 7; 
AeroDyn['B1N8Vindx']          = False     # (m/s); Axial induced wind velocity at Blade 1, Node 8; 
AeroDyn['B1N9Vindx']          = False     # (m/s); Axial induced wind velocity at Blade 1, Node 9; 
AeroDyn['B2N1Vindx']          = False     # (m/s); Axial induced wind velocity at Blade 2, Node 1; 
AeroDyn['B2N2Vindx']          = False     # (m/s); Axial induced wind velocity at Blade 2, Node 2; 
AeroDyn['B2N3Vindx']          = False     # (m/s); Axial induced wind velocity at Blade 2, Node 3; 
AeroDyn['B2N4Vindx']          = False     # (m/s); Axial induced wind velocity at Blade 2, Node 4; 
AeroDyn['B2N5Vindx']          = False     # (m/s); Axial induced wind velocity at Blade 2, Node 5; 
AeroDyn['B2N6Vindx']          = False     # (m/s); Axial induced wind velocity at Blade 2, Node 6; 
AeroDyn['B2N7Vindx']          = False     # (m/s); Axial induced wind velocity at Blade 2, Node 7; 
AeroDyn['B2N8Vindx']          = False     # (m/s); Axial induced wind velocity at Blade 2, Node 8; 
AeroDyn['B2N9Vindx']          = False     # (m/s); Axial induced wind velocity at Blade 2, Node 9; 
AeroDyn['B3N1Vindx']          = False     # (m/s); Axial induced wind velocity at Blade 3, Node 1; 
AeroDyn['B3N2Vindx']          = False     # (m/s); Axial induced wind velocity at Blade 3, Node 2; 
AeroDyn['B3N3Vindx']          = False     # (m/s); Axial induced wind velocity at Blade 3, Node 3; 
AeroDyn['B3N4Vindx']          = False     # (m/s); Axial induced wind velocity at Blade 3, Node 4; 
AeroDyn['B3N5Vindx']          = False     # (m/s); Axial induced wind velocity at Blade 3, Node 5; 
AeroDyn['B3N6Vindx']          = False     # (m/s); Axial induced wind velocity at Blade 3, Node 6; 
AeroDyn['B3N7Vindx']          = False     # (m/s); Axial induced wind velocity at Blade 3, Node 7; 
AeroDyn['B3N8Vindx']          = False     # (m/s); Axial induced wind velocity at Blade 3, Node 8; 
AeroDyn['B3N9Vindx']          = False     # (m/s); Axial induced wind velocity at Blade 3, Node 9; 
AeroDyn['B1N1Vindy']          = False     # (m/s); Tangential induced wind velocity at Blade 1, Node 1; 
AeroDyn['B1N2Vindy']          = False     # (m/s); Tangential induced wind velocity at Blade 1, Node 2; 
AeroDyn['B1N3Vindy']          = False     # (m/s); Tangential induced wind velocity at Blade 1, Node 3; 
AeroDyn['B1N4Vindy']          = False     # (m/s); Tangential induced wind velocity at Blade 1, Node 4; 
AeroDyn['B1N5Vindy']          = False     # (m/s); Tangential induced wind velocity at Blade 1, Node 5; 
AeroDyn['B1N6Vindy']          = False     # (m/s); Tangential induced wind velocity at Blade 1, Node 6; 
AeroDyn['B1N7Vindy']          = False     # (m/s); Tangential induced wind velocity at Blade 1, Node 7; 
AeroDyn['B1N8Vindy']          = False     # (m/s); Tangential induced wind velocity at Blade 1, Node 8; 
AeroDyn['B1N9Vindy']          = False     # (m/s); Tangential induced wind velocity at Blade 1, Node 9; 
AeroDyn['B2N1Vindy']          = False     # (m/s); Tangential induced wind velocity at Blade 2, Node 1; 
AeroDyn['B2N2Vindy']          = False     # (m/s); Tangential induced wind velocity at Blade 2, Node 2; 
AeroDyn['B2N3Vindy']          = False     # (m/s); Tangential induced wind velocity at Blade 2, Node 3; 
AeroDyn['B2N4Vindy']          = False     # (m/s); Tangential induced wind velocity at Blade 2, Node 4; 
AeroDyn['B2N5Vindy']          = False     # (m/s); Tangential induced wind velocity at Blade 2, Node 5; 
AeroDyn['B2N6Vindy']          = False     # (m/s); Tangential induced wind velocity at Blade 2, Node 6; 
AeroDyn['B2N7Vindy']          = False     # (m/s); Tangential induced wind velocity at Blade 2, Node 7; 
AeroDyn['B2N8Vindy']          = False     # (m/s); Tangential induced wind velocity at Blade 2, Node 8; 
AeroDyn['B2N9Vindy']          = False     # (m/s); Tangential induced wind velocity at Blade 2, Node 9; 
AeroDyn['B3N1Vindy']          = False     # (m/s); Tangential induced wind velocity at Blade 3, Node 1; 
AeroDyn['B3N2Vindy']          = False     # (m/s); Tangential induced wind velocity at Blade 3, Node 2; 
AeroDyn['B3N3Vindy']          = False     # (m/s); Tangential induced wind velocity at Blade 3, Node 3; 
AeroDyn['B3N4Vindy']          = False     # (m/s); Tangential induced wind velocity at Blade 3, Node 4; 
AeroDyn['B3N5Vindy']          = False     # (m/s); Tangential induced wind velocity at Blade 3, Node 5; 
AeroDyn['B3N6Vindy']          = False     # (m/s); Tangential induced wind velocity at Blade 3, Node 6; 
AeroDyn['B3N7Vindy']          = False     # (m/s); Tangential induced wind velocity at Blade 3, Node 7; 
AeroDyn['B3N8Vindy']          = False     # (m/s); Tangential induced wind velocity at Blade 3, Node 8; 
AeroDyn['B3N9Vindy']          = False     # (m/s); Tangential induced wind velocity at Blade 3, Node 9; 
AeroDyn['B1N1AxInd']          = False     # (-); Axial induction factor at Blade 1, Node 1; 
AeroDyn['B1N2AxInd']          = False     # (-); Axial induction factor at Blade 1, Node 2; 
AeroDyn['B1N3AxInd']          = False     # (-); Axial induction factor at Blade 1, Node 3; 
AeroDyn['B1N4AxInd']          = False     # (-); Axial induction factor at Blade 1, Node 4; 
AeroDyn['B1N5AxInd']          = False     # (-); Axial induction factor at Blade 1, Node 5; 
AeroDyn['B1N6AxInd']          = False     # (-); Axial induction factor at Blade 1, Node 6; 
AeroDyn['B1N7AxInd']          = False     # (-); Axial induction factor at Blade 1, Node 7; 
AeroDyn['B1N8AxInd']          = False     # (-); Axial induction factor at Blade 1, Node 8; 
AeroDyn['B1N9AxInd']          = False     # (-); Axial induction factor at Blade 1, Node 9; 
AeroDyn['B2N1AxInd']          = False     # (-); Axial induction factor at Blade 2, Node 1; 
AeroDyn['B2N2AxInd']          = False     # (-); Axial induction factor at Blade 2, Node 2; 
AeroDyn['B2N3AxInd']          = False     # (-); Axial induction factor at Blade 2, Node 3; 
AeroDyn['B2N4AxInd']          = False     # (-); Axial induction factor at Blade 2, Node 4; 
AeroDyn['B2N5AxInd']          = False     # (-); Axial induction factor at Blade 2, Node 5; 
AeroDyn['B2N6AxInd']          = False     # (-); Axial induction factor at Blade 2, Node 6; 
AeroDyn['B2N7AxInd']          = False     # (-); Axial induction factor at Blade 2, Node 7; 
AeroDyn['B2N8AxInd']          = False     # (-); Axial induction factor at Blade 2, Node 8; 
AeroDyn['B2N9AxInd']          = False     # (-); Axial induction factor at Blade 2, Node 9; 
AeroDyn['B3N1AxInd']          = False     # (-); Axial induction factor at Blade 3, Node 1; 
AeroDyn['B3N2AxInd']          = False     # (-); Axial induction factor at Blade 3, Node 2; 
AeroDyn['B3N3AxInd']          = False     # (-); Axial induction factor at Blade 3, Node 3; 
AeroDyn['B3N4AxInd']          = False     # (-); Axial induction factor at Blade 3, Node 4; 
AeroDyn['B3N5AxInd']          = False     # (-); Axial induction factor at Blade 3, Node 5; 
AeroDyn['B3N6AxInd']          = False     # (-); Axial induction factor at Blade 3, Node 6; 
AeroDyn['B3N7AxInd']          = False     # (-); Axial induction factor at Blade 3, Node 7; 
AeroDyn['B3N8AxInd']          = False     # (-); Axial induction factor at Blade 3, Node 8; 
AeroDyn['B3N9AxInd']          = False     # (-); Axial induction factor at Blade 3, Node 9; 
AeroDyn['B1N1TnInd']          = False     # (-); Tangential induction factor at Blade 1, Node 1; 
AeroDyn['B1N2TnInd']          = False     # (-); Tangential induction factor at Blade 1, Node 2; 
AeroDyn['B1N3TnInd']          = False     # (-); Tangential induction factor at Blade 1, Node 3; 
AeroDyn['B1N4TnInd']          = False     # (-); Tangential induction factor at Blade 1, Node 4; 
AeroDyn['B1N5TnInd']          = False     # (-); Tangential induction factor at Blade 1, Node 5; 
AeroDyn['B1N6TnInd']          = False     # (-); Tangential induction factor at Blade 1, Node 6; 
AeroDyn['B1N7TnInd']          = False     # (-); Tangential induction factor at Blade 1, Node 7; 
AeroDyn['B1N8TnInd']          = False     # (-); Tangential induction factor at Blade 1, Node 8; 
AeroDyn['B1N9TnInd']          = False     # (-); Tangential induction factor at Blade 1, Node 9; 
AeroDyn['B2N1TnInd']          = False     # (-); Tangential induction factor at Blade 2, Node 1; 
AeroDyn['B2N2TnInd']          = False     # (-); Tangential induction factor at Blade 2, Node 2; 
AeroDyn['B2N3TnInd']          = False     # (-); Tangential induction factor at Blade 2, Node 3; 
AeroDyn['B2N4TnInd']          = False     # (-); Tangential induction factor at Blade 2, Node 4; 
AeroDyn['B2N5TnInd']          = False     # (-); Tangential induction factor at Blade 2, Node 5; 
AeroDyn['B2N6TnInd']          = False     # (-); Tangential induction factor at Blade 2, Node 6; 
AeroDyn['B2N7TnInd']          = False     # (-); Tangential induction factor at Blade 2, Node 7; 
AeroDyn['B2N8TnInd']          = False     # (-); Tangential induction factor at Blade 2, Node 8; 
AeroDyn['B2N9TnInd']          = False     # (-); Tangential induction factor at Blade 2, Node 9; 
AeroDyn['B3N1TnInd']          = False     # (-); Tangential induction factor at Blade 3, Node 1; 
AeroDyn['B3N2TnInd']          = False     # (-); Tangential induction factor at Blade 3, Node 2; 
AeroDyn['B3N3TnInd']          = False     # (-); Tangential induction factor at Blade 3, Node 3; 
AeroDyn['B3N4TnInd']          = False     # (-); Tangential induction factor at Blade 3, Node 4; 
AeroDyn['B3N5TnInd']          = False     # (-); Tangential induction factor at Blade 3, Node 5; 
AeroDyn['B3N6TnInd']          = False     # (-); Tangential induction factor at Blade 3, Node 6; 
AeroDyn['B3N7TnInd']          = False     # (-); Tangential induction factor at Blade 3, Node 7; 
AeroDyn['B3N8TnInd']          = False     # (-); Tangential induction factor at Blade 3, Node 8; 
AeroDyn['B3N9TnInd']          = False     # (-); Tangential induction factor at Blade 3, Node 9; 
AeroDyn['B1N1Alpha']          = False     # (deg); Angle of attack at Blade 1, Node 1; 
AeroDyn['B1N2Alpha']          = False     # (deg); Angle of attack at Blade 1, Node 2; 
AeroDyn['B1N3Alpha']          = False     # (deg); Angle of attack at Blade 1, Node 3; 
AeroDyn['B1N4Alpha']          = False     # (deg); Angle of attack at Blade 1, Node 4; 
AeroDyn['B1N5Alpha']          = False     # (deg); Angle of attack at Blade 1, Node 5; 
AeroDyn['B1N6Alpha']          = False     # (deg); Angle of attack at Blade 1, Node 6; 
AeroDyn['B1N7Alpha']          = False     # (deg); Angle of attack at Blade 1, Node 7; 
AeroDyn['B1N8Alpha']          = False     # (deg); Angle of attack at Blade 1, Node 8; 
AeroDyn['B1N9Alpha']          = False     # (deg); Angle of attack at Blade 1, Node 9; 
AeroDyn['B2N1Alpha']          = False     # (deg); Angle of attack at Blade 2, Node 1; 
AeroDyn['B2N2Alpha']          = False     # (deg); Angle of attack at Blade 2, Node 2; 
AeroDyn['B2N3Alpha']          = False     # (deg); Angle of attack at Blade 2, Node 3; 
AeroDyn['B2N4Alpha']          = False     # (deg); Angle of attack at Blade 2, Node 4; 
AeroDyn['B2N5Alpha']          = False     # (deg); Angle of attack at Blade 2, Node 5; 
AeroDyn['B2N6Alpha']          = False     # (deg); Angle of attack at Blade 2, Node 6; 
AeroDyn['B2N7Alpha']          = False     # (deg); Angle of attack at Blade 2, Node 7; 
AeroDyn['B2N8Alpha']          = False     # (deg); Angle of attack at Blade 2, Node 8; 
AeroDyn['B2N9Alpha']          = False     # (deg); Angle of attack at Blade 2, Node 9; 
AeroDyn['B3N1Alpha']          = False     # (deg); Angle of attack at Blade 3, Node 1; 
AeroDyn['B3N2Alpha']          = False     # (deg); Angle of attack at Blade 3, Node 2; 
AeroDyn['B3N3Alpha']          = False     # (deg); Angle of attack at Blade 3, Node 3; 
AeroDyn['B3N4Alpha']          = False     # (deg); Angle of attack at Blade 3, Node 4; 
AeroDyn['B3N5Alpha']          = False     # (deg); Angle of attack at Blade 3, Node 5; 
AeroDyn['B3N6Alpha']          = False     # (deg); Angle of attack at Blade 3, Node 6; 
AeroDyn['B3N7Alpha']          = False     # (deg); Angle of attack at Blade 3, Node 7; 
AeroDyn['B3N8Alpha']          = False     # (deg); Angle of attack at Blade 3, Node 8; 
AeroDyn['B3N9Alpha']          = False     # (deg); Angle of attack at Blade 3, Node 9; 
AeroDyn['B1N1Theta']          = False     # (deg); Pitch+Twist angle at Blade 1, Node 1; 
AeroDyn['B1N2Theta']          = False     # (deg); Pitch+Twist angle at Blade 1, Node 2; 
AeroDyn['B1N3Theta']          = False     # (deg); Pitch+Twist angle at Blade 1, Node 3; 
AeroDyn['B1N4Theta']          = False     # (deg); Pitch+Twist angle at Blade 1, Node 4; 
AeroDyn['B1N5Theta']          = False     # (deg); Pitch+Twist angle at Blade 1, Node 5; 
AeroDyn['B1N6Theta']          = False     # (deg); Pitch+Twist angle at Blade 1, Node 6; 
AeroDyn['B1N7Theta']          = False     # (deg); Pitch+Twist angle at Blade 1, Node 7; 
AeroDyn['B1N8Theta']          = False     # (deg); Pitch+Twist angle at Blade 1, Node 8; 
AeroDyn['B1N9Theta']          = False     # (deg); Pitch+Twist angle at Blade 1, Node 9; 
AeroDyn['B2N1Theta']          = False     # (deg); Pitch+Twist angle at Blade 2, Node 1; 
AeroDyn['B2N2Theta']          = False     # (deg); Pitch+Twist angle at Blade 2, Node 2; 
AeroDyn['B2N3Theta']          = False     # (deg); Pitch+Twist angle at Blade 2, Node 3; 
AeroDyn['B2N4Theta']          = False     # (deg); Pitch+Twist angle at Blade 2, Node 4; 
AeroDyn['B2N5Theta']          = False     # (deg); Pitch+Twist angle at Blade 2, Node 5; 
AeroDyn['B2N6Theta']          = False     # (deg); Pitch+Twist angle at Blade 2, Node 6; 
AeroDyn['B2N7Theta']          = False     # (deg); Pitch+Twist angle at Blade 2, Node 7; 
AeroDyn['B2N8Theta']          = False     # (deg); Pitch+Twist angle at Blade 2, Node 8; 
AeroDyn['B2N9Theta']          = False     # (deg); Pitch+Twist angle at Blade 2, Node 9; 
AeroDyn['B3N1Theta']          = False     # (deg); Pitch+Twist angle at Blade 3, Node 1; 
AeroDyn['B3N2Theta']          = False     # (deg); Pitch+Twist angle at Blade 3, Node 2; 
AeroDyn['B3N3Theta']          = False     # (deg); Pitch+Twist angle at Blade 3, Node 3; 
AeroDyn['B3N4Theta']          = False     # (deg); Pitch+Twist angle at Blade 3, Node 4; 
AeroDyn['B3N5Theta']          = False     # (deg); Pitch+Twist angle at Blade 3, Node 5; 
AeroDyn['B3N6Theta']          = False     # (deg); Pitch+Twist angle at Blade 3, Node 6; 
AeroDyn['B3N7Theta']          = False     # (deg); Pitch+Twist angle at Blade 3, Node 7; 
AeroDyn['B3N8Theta']          = False     # (deg); Pitch+Twist angle at Blade 3, Node 8; 
AeroDyn['B3N9Theta']          = False     # (deg); Pitch+Twist angle at Blade 3, Node 9; 
AeroDyn['B1N1Phi']            = False     # (deg); Inflow angle at Blade 1, Node 1; 
AeroDyn['B1N2Phi']            = False     # (deg); Inflow angle at Blade 1, Node 2; 
AeroDyn['B1N3Phi']            = False     # (deg); Inflow angle at Blade 1, Node 3; 
AeroDyn['B1N4Phi']            = False     # (deg); Inflow angle at Blade 1, Node 4; 
AeroDyn['B1N5Phi']            = False     # (deg); Inflow angle at Blade 1, Node 5; 
AeroDyn['B1N6Phi']            = False     # (deg); Inflow angle at Blade 1, Node 6; 
AeroDyn['B1N7Phi']            = False     # (deg); Inflow angle at Blade 1, Node 7; 
AeroDyn['B1N8Phi']            = False     # (deg); Inflow angle at Blade 1, Node 8; 
AeroDyn['B1N9Phi']            = False     # (deg); Inflow angle at Blade 1, Node 9; 
AeroDyn['B2N1Phi']            = False     # (deg); Inflow angle at Blade 2, Node 1; 
AeroDyn['B2N2Phi']            = False     # (deg); Inflow angle at Blade 2, Node 2; 
AeroDyn['B2N3Phi']            = False     # (deg); Inflow angle at Blade 2, Node 3; 
AeroDyn['B2N4Phi']            = False     # (deg); Inflow angle at Blade 2, Node 4; 
AeroDyn['B2N5Phi']            = False     # (deg); Inflow angle at Blade 2, Node 5; 
AeroDyn['B2N6Phi']            = False     # (deg); Inflow angle at Blade 2, Node 6; 
AeroDyn['B2N7Phi']            = False     # (deg); Inflow angle at Blade 2, Node 7; 
AeroDyn['B2N8Phi']            = False     # (deg); Inflow angle at Blade 2, Node 8; 
AeroDyn['B2N9Phi']            = False     # (deg); Inflow angle at Blade 2, Node 9; 
AeroDyn['B3N1Phi']            = False     # (deg); Inflow angle at Blade 3, Node 1; 
AeroDyn['B3N2Phi']            = False     # (deg); Inflow angle at Blade 3, Node 2; 
AeroDyn['B3N3Phi']            = False     # (deg); Inflow angle at Blade 3, Node 3; 
AeroDyn['B3N4Phi']            = False     # (deg); Inflow angle at Blade 3, Node 4; 
AeroDyn['B3N5Phi']            = False     # (deg); Inflow angle at Blade 3, Node 5; 
AeroDyn['B3N6Phi']            = False     # (deg); Inflow angle at Blade 3, Node 6; 
AeroDyn['B3N7Phi']            = False     # (deg); Inflow angle at Blade 3, Node 7; 
AeroDyn['B3N8Phi']            = False     # (deg); Inflow angle at Blade 3, Node 8; 
AeroDyn['B3N9Phi']            = False     # (deg); Inflow angle at Blade 3, Node 9; 
AeroDyn['B1N1Curve']          = False     # (deg); Curvature angle at Blade 1, Node 1; 
AeroDyn['B1N2Curve']          = False     # (deg); Curvature angle at Blade 1, Node 2; 
AeroDyn['B1N3Curve']          = False     # (deg); Curvature angle at Blade 1, Node 3; 
AeroDyn['B1N4Curve']          = False     # (deg); Curvature angle at Blade 1, Node 4; 
AeroDyn['B1N5Curve']          = False     # (deg); Curvature angle at Blade 1, Node 5; 
AeroDyn['B1N6Curve']          = False     # (deg); Curvature angle at Blade 1, Node 6; 
AeroDyn['B1N7Curve']          = False     # (deg); Curvature angle at Blade 1, Node 7; 
AeroDyn['B1N8Curve']          = False     # (deg); Curvature angle at Blade 1, Node 8; 
AeroDyn['B1N9Curve']          = False     # (deg); Curvature angle at Blade 1, Node 9; 
AeroDyn['B2N1Curve']          = False     # (deg); Curvature angle at Blade 2, Node 1; 
AeroDyn['B2N2Curve']          = False     # (deg); Curvature angle at Blade 2, Node 2; 
AeroDyn['B2N3Curve']          = False     # (deg); Curvature angle at Blade 2, Node 3; 
AeroDyn['B2N4Curve']          = False     # (deg); Curvature angle at Blade 2, Node 4; 
AeroDyn['B2N5Curve']          = False     # (deg); Curvature angle at Blade 2, Node 5; 
AeroDyn['B2N6Curve']          = False     # (deg); Curvature angle at Blade 2, Node 6; 
AeroDyn['B2N7Curve']          = False     # (deg); Curvature angle at Blade 2, Node 7; 
AeroDyn['B2N8Curve']          = False     # (deg); Curvature angle at Blade 2, Node 8; 
AeroDyn['B2N9Curve']          = False     # (deg); Curvature angle at Blade 2, Node 9; 
AeroDyn['B3N1Curve']          = False     # (deg); Curvature angle at Blade 3, Node 1; 
AeroDyn['B3N2Curve']          = False     # (deg); Curvature angle at Blade 3, Node 2; 
AeroDyn['B3N3Curve']          = False     # (deg); Curvature angle at Blade 3, Node 3; 
AeroDyn['B3N4Curve']          = False     # (deg); Curvature angle at Blade 3, Node 4; 
AeroDyn['B3N5Curve']          = False     # (deg); Curvature angle at Blade 3, Node 5; 
AeroDyn['B3N6Curve']          = False     # (deg); Curvature angle at Blade 3, Node 6; 
AeroDyn['B3N7Curve']          = False     # (deg); Curvature angle at Blade 3, Node 7; 
AeroDyn['B3N8Curve']          = False     # (deg); Curvature angle at Blade 3, Node 8; 
AeroDyn['B3N9Curve']          = False     # (deg); Curvature angle at Blade 3, Node 9; 
AeroDyn['B1N1Cl']             = False     # (-); Lift force coefficient at Blade 1, Node 1; 
AeroDyn['B1N2Cl']             = False     # (-); Lift force coefficient at Blade 1, Node 2; 
AeroDyn['B1N3Cl']             = False     # (-); Lift force coefficient at Blade 1, Node 3; 
AeroDyn['B1N4Cl']             = False     # (-); Lift force coefficient at Blade 1, Node 4; 
AeroDyn['B1N5Cl']             = False     # (-); Lift force coefficient at Blade 1, Node 5; 
AeroDyn['B1N6Cl']             = False     # (-); Lift force coefficient at Blade 1, Node 6; 
AeroDyn['B1N7Cl']             = False     # (-); Lift force coefficient at Blade 1, Node 7; 
AeroDyn['B1N8Cl']             = False     # (-); Lift force coefficient at Blade 1, Node 8; 
AeroDyn['B1N9Cl']             = False     # (-); Lift force coefficient at Blade 1, Node 9; 
AeroDyn['B2N1Cl']             = False     # (-); Lift force coefficient at Blade 2, Node 1; 
AeroDyn['B2N2Cl']             = False     # (-); Lift force coefficient at Blade 2, Node 2; 
AeroDyn['B2N3Cl']             = False     # (-); Lift force coefficient at Blade 2, Node 3; 
AeroDyn['B2N4Cl']             = False     # (-); Lift force coefficient at Blade 2, Node 4; 
AeroDyn['B2N5Cl']             = False     # (-); Lift force coefficient at Blade 2, Node 5; 
AeroDyn['B2N6Cl']             = False     # (-); Lift force coefficient at Blade 2, Node 6; 
AeroDyn['B2N7Cl']             = False     # (-); Lift force coefficient at Blade 2, Node 7; 
AeroDyn['B2N8Cl']             = False     # (-); Lift force coefficient at Blade 2, Node 8; 
AeroDyn['B2N9Cl']             = False     # (-); Lift force coefficient at Blade 2, Node 9; 
AeroDyn['B3N1Cl']             = False     # (-); Lift force coefficient at Blade 3, Node 1; 
AeroDyn['B3N2Cl']             = False     # (-); Lift force coefficient at Blade 3, Node 2; 
AeroDyn['B3N3Cl']             = False     # (-); Lift force coefficient at Blade 3, Node 3; 
AeroDyn['B3N4Cl']             = False     # (-); Lift force coefficient at Blade 3, Node 4; 
AeroDyn['B3N5Cl']             = False     # (-); Lift force coefficient at Blade 3, Node 5; 
AeroDyn['B3N6Cl']             = False     # (-); Lift force coefficient at Blade 3, Node 6; 
AeroDyn['B3N7Cl']             = False     # (-); Lift force coefficient at Blade 3, Node 7; 
AeroDyn['B3N8Cl']             = False     # (-); Lift force coefficient at Blade 3, Node 8; 
AeroDyn['B3N9Cl']             = False     # (-); Lift force coefficient at Blade 3, Node 9; 
AeroDyn['B1N1Cd']             = False     # (-); Drag force coefficient at Blade 1, Node 1; 
AeroDyn['B1N2Cd']             = False     # (-); Drag force coefficient at Blade 1, Node 2; 
AeroDyn['B1N3Cd']             = False     # (-); Drag force coefficient at Blade 1, Node 3; 
AeroDyn['B1N4Cd']             = False     # (-); Drag force coefficient at Blade 1, Node 4; 
AeroDyn['B1N5Cd']             = False     # (-); Drag force coefficient at Blade 1, Node 5; 
AeroDyn['B1N6Cd']             = False     # (-); Drag force coefficient at Blade 1, Node 6; 
AeroDyn['B1N7Cd']             = False     # (-); Drag force coefficient at Blade 1, Node 7; 
AeroDyn['B1N8Cd']             = False     # (-); Drag force coefficient at Blade 1, Node 8; 
AeroDyn['B1N9Cd']             = False     # (-); Drag force coefficient at Blade 1, Node 9; 
AeroDyn['B2N1Cd']             = False     # (-); Drag force coefficient at Blade 2, Node 1; 
AeroDyn['B2N2Cd']             = False     # (-); Drag force coefficient at Blade 2, Node 2; 
AeroDyn['B2N3Cd']             = False     # (-); Drag force coefficient at Blade 2, Node 3; 
AeroDyn['B2N4Cd']             = False     # (-); Drag force coefficient at Blade 2, Node 4; 
AeroDyn['B2N5Cd']             = False     # (-); Drag force coefficient at Blade 2, Node 5; 
AeroDyn['B2N6Cd']             = False     # (-); Drag force coefficient at Blade 2, Node 6; 
AeroDyn['B2N7Cd']             = False     # (-); Drag force coefficient at Blade 2, Node 7; 
AeroDyn['B2N8Cd']             = False     # (-); Drag force coefficient at Blade 2, Node 8; 
AeroDyn['B2N9Cd']             = False     # (-); Drag force coefficient at Blade 2, Node 9; 
AeroDyn['B3N1Cd']             = False     # (-); Drag force coefficient at Blade 3, Node 1; 
AeroDyn['B3N2Cd']             = False     # (-); Drag force coefficient at Blade 3, Node 2; 
AeroDyn['B3N3Cd']             = False     # (-); Drag force coefficient at Blade 3, Node 3; 
AeroDyn['B3N4Cd']             = False     # (-); Drag force coefficient at Blade 3, Node 4; 
AeroDyn['B3N5Cd']             = False     # (-); Drag force coefficient at Blade 3, Node 5; 
AeroDyn['B3N6Cd']             = False     # (-); Drag force coefficient at Blade 3, Node 6; 
AeroDyn['B3N7Cd']             = False     # (-); Drag force coefficient at Blade 3, Node 7; 
AeroDyn['B3N8Cd']             = False     # (-); Drag force coefficient at Blade 3, Node 8; 
AeroDyn['B3N9Cd']             = False     # (-); Drag force coefficient at Blade 3, Node 9; 
AeroDyn['B1N1Cm']             = False     # (-); Pitching moment coefficient at Blade 1, Node 1; 
AeroDyn['B1N2Cm']             = False     # (-); Pitching moment coefficient at Blade 1, Node 2; 
AeroDyn['B1N3Cm']             = False     # (-); Pitching moment coefficient at Blade 1, Node 3; 
AeroDyn['B1N4Cm']             = False     # (-); Pitching moment coefficient at Blade 1, Node 4; 
AeroDyn['B1N5Cm']             = False     # (-); Pitching moment coefficient at Blade 1, Node 5; 
AeroDyn['B1N6Cm']             = False     # (-); Pitching moment coefficient at Blade 1, Node 6; 
AeroDyn['B1N7Cm']             = False     # (-); Pitching moment coefficient at Blade 1, Node 7; 
AeroDyn['B1N8Cm']             = False     # (-); Pitching moment coefficient at Blade 1, Node 8; 
AeroDyn['B1N9Cm']             = False     # (-); Pitching moment coefficient at Blade 1, Node 9; 
AeroDyn['B2N1Cm']             = False     # (-); Pitching moment coefficient at Blade 2, Node 1; 
AeroDyn['B2N2Cm']             = False     # (-); Pitching moment coefficient at Blade 2, Node 2; 
AeroDyn['B2N3Cm']             = False     # (-); Pitching moment coefficient at Blade 2, Node 3; 
AeroDyn['B2N4Cm']             = False     # (-); Pitching moment coefficient at Blade 2, Node 4; 
AeroDyn['B2N5Cm']             = False     # (-); Pitching moment coefficient at Blade 2, Node 5; 
AeroDyn['B2N6Cm']             = False     # (-); Pitching moment coefficient at Blade 2, Node 6; 
AeroDyn['B2N7Cm']             = False     # (-); Pitching moment coefficient at Blade 2, Node 7; 
AeroDyn['B2N8Cm']             = False     # (-); Pitching moment coefficient at Blade 2, Node 8; 
AeroDyn['B2N9Cm']             = False     # (-); Pitching moment coefficient at Blade 2, Node 9; 
AeroDyn['B3N1Cm']             = False     # (-); Pitching moment coefficient at Blade 3, Node 1; 
AeroDyn['B3N2Cm']             = False     # (-); Pitching moment coefficient at Blade 3, Node 2; 
AeroDyn['B3N3Cm']             = False     # (-); Pitching moment coefficient at Blade 3, Node 3; 
AeroDyn['B3N4Cm']             = False     # (-); Pitching moment coefficient at Blade 3, Node 4; 
AeroDyn['B3N5Cm']             = False     # (-); Pitching moment coefficient at Blade 3, Node 5; 
AeroDyn['B3N6Cm']             = False     # (-); Pitching moment coefficient at Blade 3, Node 6; 
AeroDyn['B3N7Cm']             = False     # (-); Pitching moment coefficient at Blade 3, Node 7; 
AeroDyn['B3N8Cm']             = False     # (-); Pitching moment coefficient at Blade 3, Node 8; 
AeroDyn['B3N9Cm']             = False     # (-); Pitching moment coefficient at Blade 3, Node 9; 
AeroDyn['B1N1Cx']             = False     # (-); Normal force (to plane) coefficient at Blade 1, Node 1; 
AeroDyn['B1N2Cx']             = False     # (-); Normal force (to plane) coefficient at Blade 1, Node 2; 
AeroDyn['B1N3Cx']             = False     # (-); Normal force (to plane) coefficient at Blade 1, Node 3; 
AeroDyn['B1N4Cx']             = False     # (-); Normal force (to plane) coefficient at Blade 1, Node 4; 
AeroDyn['B1N5Cx']             = False     # (-); Normal force (to plane) coefficient at Blade 1, Node 5; 
AeroDyn['B1N6Cx']             = False     # (-); Normal force (to plane) coefficient at Blade 1, Node 6; 
AeroDyn['B1N7Cx']             = False     # (-); Normal force (to plane) coefficient at Blade 1, Node 7; 
AeroDyn['B1N8Cx']             = False     # (-); Normal force (to plane) coefficient at Blade 1, Node 8; 
AeroDyn['B1N9Cx']             = False     # (-); Normal force (to plane) coefficient at Blade 1, Node 9; 
AeroDyn['B2N1Cx']             = False     # (-); Normal force (to plane) coefficient at Blade 2, Node 1; 
AeroDyn['B2N2Cx']             = False     # (-); Normal force (to plane) coefficient at Blade 2, Node 2; 
AeroDyn['B2N3Cx']             = False     # (-); Normal force (to plane) coefficient at Blade 2, Node 3; 
AeroDyn['B2N4Cx']             = False     # (-); Normal force (to plane) coefficient at Blade 2, Node 4; 
AeroDyn['B2N5Cx']             = False     # (-); Normal force (to plane) coefficient at Blade 2, Node 5; 
AeroDyn['B2N6Cx']             = False     # (-); Normal force (to plane) coefficient at Blade 2, Node 6; 
AeroDyn['B2N7Cx']             = False     # (-); Normal force (to plane) coefficient at Blade 2, Node 7; 
AeroDyn['B2N8Cx']             = False     # (-); Normal force (to plane) coefficient at Blade 2, Node 8; 
AeroDyn['B2N9Cx']             = False     # (-); Normal force (to plane) coefficient at Blade 2, Node 9; 
AeroDyn['B3N1Cx']             = False     # (-); Normal force (to plane) coefficient at Blade 3, Node 1; 
AeroDyn['B3N2Cx']             = False     # (-); Normal force (to plane) coefficient at Blade 3, Node 2; 
AeroDyn['B3N3Cx']             = False     # (-); Normal force (to plane) coefficient at Blade 3, Node 3; 
AeroDyn['B3N4Cx']             = False     # (-); Normal force (to plane) coefficient at Blade 3, Node 4; 
AeroDyn['B3N5Cx']             = False     # (-); Normal force (to plane) coefficient at Blade 3, Node 5; 
AeroDyn['B3N6Cx']             = False     # (-); Normal force (to plane) coefficient at Blade 3, Node 6; 
AeroDyn['B3N7Cx']             = False     # (-); Normal force (to plane) coefficient at Blade 3, Node 7; 
AeroDyn['B3N8Cx']             = False     # (-); Normal force (to plane) coefficient at Blade 3, Node 8; 
AeroDyn['B3N9Cx']             = False     # (-); Normal force (to plane) coefficient at Blade 3, Node 9; 
AeroDyn['B1N1Cy']             = False     # (-); Tangential force (to plane) coefficient at Blade 1, Node 1; 
AeroDyn['B1N2Cy']             = False     # (-); Tangential force (to plane) coefficient at Blade 1, Node 2; 
AeroDyn['B1N3Cy']             = False     # (-); Tangential force (to plane) coefficient at Blade 1, Node 3; 
AeroDyn['B1N4Cy']             = False     # (-); Tangential force (to plane) coefficient at Blade 1, Node 4; 
AeroDyn['B1N5Cy']             = False     # (-); Tangential force (to plane) coefficient at Blade 1, Node 5; 
AeroDyn['B1N6Cy']             = False     # (-); Tangential force (to plane) coefficient at Blade 1, Node 6; 
AeroDyn['B1N7Cy']             = False     # (-); Tangential force (to plane) coefficient at Blade 1, Node 7; 
AeroDyn['B1N8Cy']             = False     # (-); Tangential force (to plane) coefficient at Blade 1, Node 8; 
AeroDyn['B1N9Cy']             = False     # (-); Tangential force (to plane) coefficient at Blade 1, Node 9; 
AeroDyn['B2N1Cy']             = False     # (-); Tangential force (to plane) coefficient at Blade 2, Node 1; 
AeroDyn['B2N2Cy']             = False     # (-); Tangential force (to plane) coefficient at Blade 2, Node 2; 
AeroDyn['B2N3Cy']             = False     # (-); Tangential force (to plane) coefficient at Blade 2, Node 3; 
AeroDyn['B2N4Cy']             = False     # (-); Tangential force (to plane) coefficient at Blade 2, Node 4; 
AeroDyn['B2N5Cy']             = False     # (-); Tangential force (to plane) coefficient at Blade 2, Node 5; 
AeroDyn['B2N6Cy']             = False     # (-); Tangential force (to plane) coefficient at Blade 2, Node 6; 
AeroDyn['B2N7Cy']             = False     # (-); Tangential force (to plane) coefficient at Blade 2, Node 7; 
AeroDyn['B2N8Cy']             = False     # (-); Tangential force (to plane) coefficient at Blade 2, Node 8; 
AeroDyn['B2N9Cy']             = False     # (-); Tangential force (to plane) coefficient at Blade 2, Node 9; 
AeroDyn['B3N1Cy']             = False     # (-); Tangential force (to plane) coefficient at Blade 3, Node 1; 
AeroDyn['B3N2Cy']             = False     # (-); Tangential force (to plane) coefficient at Blade 3, Node 2; 
AeroDyn['B3N3Cy']             = False     # (-); Tangential force (to plane) coefficient at Blade 3, Node 3; 
AeroDyn['B3N4Cy']             = False     # (-); Tangential force (to plane) coefficient at Blade 3, Node 4; 
AeroDyn['B3N5Cy']             = False     # (-); Tangential force (to plane) coefficient at Blade 3, Node 5; 
AeroDyn['B3N6Cy']             = False     # (-); Tangential force (to plane) coefficient at Blade 3, Node 6; 
AeroDyn['B3N7Cy']             = False     # (-); Tangential force (to plane) coefficient at Blade 3, Node 7; 
AeroDyn['B3N8Cy']             = False     # (-); Tangential force (to plane) coefficient at Blade 3, Node 8; 
AeroDyn['B3N9Cy']             = False     # (-); Tangential force (to plane) coefficient at Blade 3, Node 9; 
AeroDyn['B1N1Cn']             = False     # (-); Normal force (to chord) coefficient at Blade 1, Node 1; 
AeroDyn['B1N2Cn']             = False     # (-); Normal force (to chord) coefficient at Blade 1, Node 2; 
AeroDyn['B1N3Cn']             = False     # (-); Normal force (to chord) coefficient at Blade 1, Node 3; 
AeroDyn['B1N4Cn']             = False     # (-); Normal force (to chord) coefficient at Blade 1, Node 4; 
AeroDyn['B1N5Cn']             = False     # (-); Normal force (to chord) coefficient at Blade 1, Node 5; 
AeroDyn['B1N6Cn']             = False     # (-); Normal force (to chord) coefficient at Blade 1, Node 6; 
AeroDyn['B1N7Cn']             = False     # (-); Normal force (to chord) coefficient at Blade 1, Node 7; 
AeroDyn['B1N8Cn']             = False     # (-); Normal force (to chord) coefficient at Blade 1, Node 8; 
AeroDyn['B1N9Cn']             = False     # (-); Normal force (to chord) coefficient at Blade 1, Node 9; 
AeroDyn['B2N1Cn']             = False     # (-); Normal force (to chord) coefficient at Blade 2, Node 1; 
AeroDyn['B2N2Cn']             = False     # (-); Normal force (to chord) coefficient at Blade 2, Node 2; 
AeroDyn['B2N3Cn']             = False     # (-); Normal force (to chord) coefficient at Blade 2, Node 3; 
AeroDyn['B2N4Cn']             = False     # (-); Normal force (to chord) coefficient at Blade 2, Node 4; 
AeroDyn['B2N5Cn']             = False     # (-); Normal force (to chord) coefficient at Blade 2, Node 5; 
AeroDyn['B2N6Cn']             = False     # (-); Normal force (to chord) coefficient at Blade 2, Node 6; 
AeroDyn['B2N7Cn']             = False     # (-); Normal force (to chord) coefficient at Blade 2, Node 7; 
AeroDyn['B2N8Cn']             = False     # (-); Normal force (to chord) coefficient at Blade 2, Node 8; 
AeroDyn['B2N9Cn']             = False     # (-); Normal force (to chord) coefficient at Blade 2, Node 9; 
AeroDyn['B3N1Cn']             = False     # (-); Normal force (to chord) coefficient at Blade 3, Node 1; 
AeroDyn['B3N2Cn']             = False     # (-); Normal force (to chord) coefficient at Blade 3, Node 2; 
AeroDyn['B3N3Cn']             = False     # (-); Normal force (to chord) coefficient at Blade 3, Node 3; 
AeroDyn['B3N4Cn']             = False     # (-); Normal force (to chord) coefficient at Blade 3, Node 4; 
AeroDyn['B3N5Cn']             = False     # (-); Normal force (to chord) coefficient at Blade 3, Node 5; 
AeroDyn['B3N6Cn']             = False     # (-); Normal force (to chord) coefficient at Blade 3, Node 6; 
AeroDyn['B3N7Cn']             = False     # (-); Normal force (to chord) coefficient at Blade 3, Node 7; 
AeroDyn['B3N8Cn']             = False     # (-); Normal force (to chord) coefficient at Blade 3, Node 8; 
AeroDyn['B3N9Cn']             = False     # (-); Normal force (to chord) coefficient at Blade 3, Node 9; 
AeroDyn['B1N1Ct']             = False     # (-); Tangential force (to chord) coefficient at Blade 1, Node 1; 
AeroDyn['B1N2Ct']             = False     # (-); Tangential force (to chord) coefficient at Blade 1, Node 2; 
AeroDyn['B1N3Ct']             = False     # (-); Tangential force (to chord) coefficient at Blade 1, Node 3; 
AeroDyn['B1N4Ct']             = False     # (-); Tangential force (to chord) coefficient at Blade 1, Node 4; 
AeroDyn['B1N5Ct']             = False     # (-); Tangential force (to chord) coefficient at Blade 1, Node 5; 
AeroDyn['B1N6Ct']             = False     # (-); Tangential force (to chord) coefficient at Blade 1, Node 6; 
AeroDyn['B1N7Ct']             = False     # (-); Tangential force (to chord) coefficient at Blade 1, Node 7; 
AeroDyn['B1N8Ct']             = False     # (-); Tangential force (to chord) coefficient at Blade 1, Node 8; 
AeroDyn['B1N9Ct']             = False     # (-); Tangential force (to chord) coefficient at Blade 1, Node 9; 
AeroDyn['B2N1Ct']             = False     # (-); Tangential force (to chord) coefficient at Blade 2, Node 1; 
AeroDyn['B2N2Ct']             = False     # (-); Tangential force (to chord) coefficient at Blade 2, Node 2; 
AeroDyn['B2N3Ct']             = False     # (-); Tangential force (to chord) coefficient at Blade 2, Node 3; 
AeroDyn['B2N4Ct']             = False     # (-); Tangential force (to chord) coefficient at Blade 2, Node 4; 
AeroDyn['B2N5Ct']             = False     # (-); Tangential force (to chord) coefficient at Blade 2, Node 5; 
AeroDyn['B2N6Ct']             = False     # (-); Tangential force (to chord) coefficient at Blade 2, Node 6; 
AeroDyn['B2N7Ct']             = False     # (-); Tangential force (to chord) coefficient at Blade 2, Node 7; 
AeroDyn['B2N8Ct']             = False     # (-); Tangential force (to chord) coefficient at Blade 2, Node 8; 
AeroDyn['B2N9Ct']             = False     # (-); Tangential force (to chord) coefficient at Blade 2, Node 9; 
AeroDyn['B3N1Ct']             = False     # (-); Tangential force (to chord) coefficient at Blade 3, Node 1; 
AeroDyn['B3N2Ct']             = False     # (-); Tangential force (to chord) coefficient at Blade 3, Node 2; 
AeroDyn['B3N3Ct']             = False     # (-); Tangential force (to chord) coefficient at Blade 3, Node 3; 
AeroDyn['B3N4Ct']             = False     # (-); Tangential force (to chord) coefficient at Blade 3, Node 4; 
AeroDyn['B3N5Ct']             = False     # (-); Tangential force (to chord) coefficient at Blade 3, Node 5; 
AeroDyn['B3N6Ct']             = False     # (-); Tangential force (to chord) coefficient at Blade 3, Node 6; 
AeroDyn['B3N7Ct']             = False     # (-); Tangential force (to chord) coefficient at Blade 3, Node 7; 
AeroDyn['B3N8Ct']             = False     # (-); Tangential force (to chord) coefficient at Blade 3, Node 8; 
AeroDyn['B3N9Ct']             = False     # (-); Tangential force (to chord) coefficient at Blade 3, Node 9; 
AeroDyn['B1N1Fl']             = False     # (N/m); Lift force per unit length at Blade 1, Node 1; 
AeroDyn['B1N2Fl']             = False     # (N/m); Lift force per unit length at Blade 1, Node 2; 
AeroDyn['B1N3Fl']             = False     # (N/m); Lift force per unit length at Blade 1, Node 3; 
AeroDyn['B1N4Fl']             = False     # (N/m); Lift force per unit length at Blade 1, Node 4; 
AeroDyn['B1N5Fl']             = False     # (N/m); Lift force per unit length at Blade 1, Node 5; 
AeroDyn['B1N6Fl']             = False     # (N/m); Lift force per unit length at Blade 1, Node 6; 
AeroDyn['B1N7Fl']             = False     # (N/m); Lift force per unit length at Blade 1, Node 7; 
AeroDyn['B1N8Fl']             = False     # (N/m); Lift force per unit length at Blade 1, Node 8; 
AeroDyn['B1N9Fl']             = False     # (N/m); Lift force per unit length at Blade 1, Node 9; 
AeroDyn['B2N1Fl']             = False     # (N/m); Lift force per unit length at Blade 2, Node 1; 
AeroDyn['B2N2Fl']             = False     # (N/m); Lift force per unit length at Blade 2, Node 2; 
AeroDyn['B2N3Fl']             = False     # (N/m); Lift force per unit length at Blade 2, Node 3; 
AeroDyn['B2N4Fl']             = False     # (N/m); Lift force per unit length at Blade 2, Node 4; 
AeroDyn['B2N5Fl']             = False     # (N/m); Lift force per unit length at Blade 2, Node 5; 
AeroDyn['B2N6Fl']             = False     # (N/m); Lift force per unit length at Blade 2, Node 6; 
AeroDyn['B2N7Fl']             = False     # (N/m); Lift force per unit length at Blade 2, Node 7; 
AeroDyn['B2N8Fl']             = False     # (N/m); Lift force per unit length at Blade 2, Node 8; 
AeroDyn['B2N9Fl']             = False     # (N/m); Lift force per unit length at Blade 2, Node 9; 
AeroDyn['B3N1Fl']             = False     # (N/m); Lift force per unit length at Blade 3, Node 1; 
AeroDyn['B3N2Fl']             = False     # (N/m); Lift force per unit length at Blade 3, Node 2; 
AeroDyn['B3N3Fl']             = False     # (N/m); Lift force per unit length at Blade 3, Node 3; 
AeroDyn['B3N4Fl']             = False     # (N/m); Lift force per unit length at Blade 3, Node 4; 
AeroDyn['B3N5Fl']             = False     # (N/m); Lift force per unit length at Blade 3, Node 5; 
AeroDyn['B3N6Fl']             = False     # (N/m); Lift force per unit length at Blade 3, Node 6; 
AeroDyn['B3N7Fl']             = False     # (N/m); Lift force per unit length at Blade 3, Node 7; 
AeroDyn['B3N8Fl']             = False     # (N/m); Lift force per unit length at Blade 3, Node 8; 
AeroDyn['B3N9Fl']             = False     # (N/m); Lift force per unit length at Blade 3, Node 9; 
AeroDyn['B1N1Fd']             = False     # (N/m); Drag force per unit length at Blade 1, Node 1; 
AeroDyn['B1N2Fd']             = False     # (N/m); Drag force per unit length at Blade 1, Node 2; 
AeroDyn['B1N3Fd']             = False     # (N/m); Drag force per unit length at Blade 1, Node 3; 
AeroDyn['B1N4Fd']             = False     # (N/m); Drag force per unit length at Blade 1, Node 4; 
AeroDyn['B1N5Fd']             = False     # (N/m); Drag force per unit length at Blade 1, Node 5; 
AeroDyn['B1N6Fd']             = False     # (N/m); Drag force per unit length at Blade 1, Node 6; 
AeroDyn['B1N7Fd']             = False     # (N/m); Drag force per unit length at Blade 1, Node 7; 
AeroDyn['B1N8Fd']             = False     # (N/m); Drag force per unit length at Blade 1, Node 8; 
AeroDyn['B1N9Fd']             = False     # (N/m); Drag force per unit length at Blade 1, Node 9; 
AeroDyn['B2N1Fd']             = False     # (N/m); Drag force per unit length at Blade 2, Node 1; 
AeroDyn['B2N2Fd']             = False     # (N/m); Drag force per unit length at Blade 2, Node 2; 
AeroDyn['B2N3Fd']             = False     # (N/m); Drag force per unit length at Blade 2, Node 3; 
AeroDyn['B2N4Fd']             = False     # (N/m); Drag force per unit length at Blade 2, Node 4; 
AeroDyn['B2N5Fd']             = False     # (N/m); Drag force per unit length at Blade 2, Node 5; 
AeroDyn['B2N6Fd']             = False     # (N/m); Drag force per unit length at Blade 2, Node 6; 
AeroDyn['B2N7Fd']             = False     # (N/m); Drag force per unit length at Blade 2, Node 7; 
AeroDyn['B2N8Fd']             = False     # (N/m); Drag force per unit length at Blade 2, Node 8; 
AeroDyn['B2N9Fd']             = False     # (N/m); Drag force per unit length at Blade 2, Node 9; 
AeroDyn['B3N1Fd']             = False     # (N/m); Drag force per unit length at Blade 3, Node 1; 
AeroDyn['B3N2Fd']             = False     # (N/m); Drag force per unit length at Blade 3, Node 2; 
AeroDyn['B3N3Fd']             = False     # (N/m); Drag force per unit length at Blade 3, Node 3; 
AeroDyn['B3N4Fd']             = False     # (N/m); Drag force per unit length at Blade 3, Node 4; 
AeroDyn['B3N5Fd']             = False     # (N/m); Drag force per unit length at Blade 3, Node 5; 
AeroDyn['B3N6Fd']             = False     # (N/m); Drag force per unit length at Blade 3, Node 6; 
AeroDyn['B3N7Fd']             = False     # (N/m); Drag force per unit length at Blade 3, Node 7; 
AeroDyn['B3N8Fd']             = False     # (N/m); Drag force per unit length at Blade 3, Node 8; 
AeroDyn['B3N9Fd']             = False     # (N/m); Drag force per unit length at Blade 3, Node 9; 
AeroDyn['B1N1Mm']             = False     # (N-m/m); Pitching moment per unit length at Blade 1, Node 1; 
AeroDyn['B1N2Mm']             = False     # (N-m/m); Pitching moment per unit length at Blade 1, Node 2; 
AeroDyn['B1N3Mm']             = False     # (N-m/m); Pitching moment per unit length at Blade 1, Node 3; 
AeroDyn['B1N4Mm']             = False     # (N-m/m); Pitching moment per unit length at Blade 1, Node 4; 
AeroDyn['B1N5Mm']             = False     # (N-m/m); Pitching moment per unit length at Blade 1, Node 5; 
AeroDyn['B1N6Mm']             = False     # (N-m/m); Pitching moment per unit length at Blade 1, Node 6; 
AeroDyn['B1N7Mm']             = False     # (N-m/m); Pitching moment per unit length at Blade 1, Node 7; 
AeroDyn['B1N8Mm']             = False     # (N-m/m); Pitching moment per unit length at Blade 1, Node 8; 
AeroDyn['B1N9Mm']             = False     # (N-m/m); Pitching moment per unit length at Blade 1, Node 9; 
AeroDyn['B2N1Mm']             = False     # (N-m/m); Pitching moment per unit length at Blade 2, Node 1; 
AeroDyn['B2N2Mm']             = False     # (N-m/m); Pitching moment per unit length at Blade 2, Node 2; 
AeroDyn['B2N3Mm']             = False     # (N-m/m); Pitching moment per unit length at Blade 2, Node 3; 
AeroDyn['B2N4Mm']             = False     # (N-m/m); Pitching moment per unit length at Blade 2, Node 4; 
AeroDyn['B2N5Mm']             = False     # (N-m/m); Pitching moment per unit length at Blade 2, Node 5; 
AeroDyn['B2N6Mm']             = False     # (N-m/m); Pitching moment per unit length at Blade 2, Node 6; 
AeroDyn['B2N7Mm']             = False     # (N-m/m); Pitching moment per unit length at Blade 2, Node 7; 
AeroDyn['B2N8Mm']             = False     # (N-m/m); Pitching moment per unit length at Blade 2, Node 8; 
AeroDyn['B2N9Mm']             = False     # (N-m/m); Pitching moment per unit length at Blade 2, Node 9; 
AeroDyn['B3N1Mm']             = False     # (N-m/m); Pitching moment per unit length at Blade 3, Node 1; 
AeroDyn['B3N2Mm']             = False     # (N-m/m); Pitching moment per unit length at Blade 3, Node 2; 
AeroDyn['B3N3Mm']             = False     # (N-m/m); Pitching moment per unit length at Blade 3, Node 3; 
AeroDyn['B3N4Mm']             = False     # (N-m/m); Pitching moment per unit length at Blade 3, Node 4; 
AeroDyn['B3N5Mm']             = False     # (N-m/m); Pitching moment per unit length at Blade 3, Node 5; 
AeroDyn['B3N6Mm']             = False     # (N-m/m); Pitching moment per unit length at Blade 3, Node 6; 
AeroDyn['B3N7Mm']             = False     # (N-m/m); Pitching moment per unit length at Blade 3, Node 7; 
AeroDyn['B3N8Mm']             = False     # (N-m/m); Pitching moment per unit length at Blade 3, Node 8; 
AeroDyn['B3N9Mm']             = False     # (N-m/m); Pitching moment per unit length at Blade 3, Node 9; 
AeroDyn['B1N1Fx']             = False     # (N/m); Normal force (to plane) per unit length at Blade 1, Node 1; 
AeroDyn['B1N2Fx']             = False     # (N/m); Normal force (to plane) per unit length at Blade 1, Node 2; 
AeroDyn['B1N3Fx']             = False     # (N/m); Normal force (to plane) per unit length at Blade 1, Node 3; 
AeroDyn['B1N4Fx']             = False     # (N/m); Normal force (to plane) per unit length at Blade 1, Node 4; 
AeroDyn['B1N5Fx']             = False     # (N/m); Normal force (to plane) per unit length at Blade 1, Node 5; 
AeroDyn['B1N6Fx']             = False     # (N/m); Normal force (to plane) per unit length at Blade 1, Node 6; 
AeroDyn['B1N7Fx']             = False     # (N/m); Normal force (to plane) per unit length at Blade 1, Node 7; 
AeroDyn['B1N8Fx']             = False     # (N/m); Normal force (to plane) per unit length at Blade 1, Node 8; 
AeroDyn['B1N9Fx']             = False     # (N/m); Normal force (to plane) per unit length at Blade 1, Node 9; 
AeroDyn['B2N1Fx']             = False     # (N/m); Normal force (to plane) per unit length at Blade 2, Node 1; 
AeroDyn['B2N2Fx']             = False     # (N/m); Normal force (to plane) per unit length at Blade 2, Node 2; 
AeroDyn['B2N3Fx']             = False     # (N/m); Normal force (to plane) per unit length at Blade 2, Node 3; 
AeroDyn['B2N4Fx']             = False     # (N/m); Normal force (to plane) per unit length at Blade 2, Node 4; 
AeroDyn['B2N5Fx']             = False     # (N/m); Normal force (to plane) per unit length at Blade 2, Node 5; 
AeroDyn['B2N6Fx']             = False     # (N/m); Normal force (to plane) per unit length at Blade 2, Node 6; 
AeroDyn['B2N7Fx']             = False     # (N/m); Normal force (to plane) per unit length at Blade 2, Node 7; 
AeroDyn['B2N8Fx']             = False     # (N/m); Normal force (to plane) per unit length at Blade 2, Node 8; 
AeroDyn['B2N9Fx']             = False     # (N/m); Normal force (to plane) per unit length at Blade 2, Node 9; 
AeroDyn['B3N1Fx']             = False     # (N/m); Normal force (to plane) per unit length at Blade 3, Node 1; 
AeroDyn['B3N2Fx']             = False     # (N/m); Normal force (to plane) per unit length at Blade 3, Node 2; 
AeroDyn['B3N3Fx']             = False     # (N/m); Normal force (to plane) per unit length at Blade 3, Node 3; 
AeroDyn['B3N4Fx']             = False     # (N/m); Normal force (to plane) per unit length at Blade 3, Node 4; 
AeroDyn['B3N5Fx']             = False     # (N/m); Normal force (to plane) per unit length at Blade 3, Node 5; 
AeroDyn['B3N6Fx']             = False     # (N/m); Normal force (to plane) per unit length at Blade 3, Node 6; 
AeroDyn['B3N7Fx']             = False     # (N/m); Normal force (to plane) per unit length at Blade 3, Node 7; 
AeroDyn['B3N8Fx']             = False     # (N/m); Normal force (to plane) per unit length at Blade 3, Node 8; 
AeroDyn['B3N9Fx']             = False     # (N/m); Normal force (to plane) per unit length at Blade 3, Node 9; 
AeroDyn['B1N1Fy']             = False     # (N/m); Tangential force (to plane) per unit length at Blade 1, Node 1; 
AeroDyn['B1N2Fy']             = False     # (N/m); Tangential force (to plane) per unit length at Blade 1, Node 2; 
AeroDyn['B1N3Fy']             = False     # (N/m); Tangential force (to plane) per unit length at Blade 1, Node 3; 
AeroDyn['B1N4Fy']             = False     # (N/m); Tangential force (to plane) per unit length at Blade 1, Node 4; 
AeroDyn['B1N5Fy']             = False     # (N/m); Tangential force (to plane) per unit length at Blade 1, Node 5; 
AeroDyn['B1N6Fy']             = False     # (N/m); Tangential force (to plane) per unit length at Blade 1, Node 6; 
AeroDyn['B1N7Fy']             = False     # (N/m); Tangential force (to plane) per unit length at Blade 1, Node 7; 
AeroDyn['B1N8Fy']             = False     # (N/m); Tangential force (to plane) per unit length at Blade 1, Node 8; 
AeroDyn['B1N9Fy']             = False     # (N/m); Tangential force (to plane) per unit length at Blade 1, Node 9; 
AeroDyn['B2N1Fy']             = False     # (N/m); Tangential force (to plane) per unit length at Blade 2, Node 1; 
AeroDyn['B2N2Fy']             = False     # (N/m); Tangential force (to plane) per unit length at Blade 2, Node 2; 
AeroDyn['B2N3Fy']             = False     # (N/m); Tangential force (to plane) per unit length at Blade 2, Node 3; 
AeroDyn['B2N4Fy']             = False     # (N/m); Tangential force (to plane) per unit length at Blade 2, Node 4; 
AeroDyn['B2N5Fy']             = False     # (N/m); Tangential force (to plane) per unit length at Blade 2, Node 5; 
AeroDyn['B2N6Fy']             = False     # (N/m); Tangential force (to plane) per unit length at Blade 2, Node 6; 
AeroDyn['B2N7Fy']             = False     # (N/m); Tangential force (to plane) per unit length at Blade 2, Node 7; 
AeroDyn['B2N8Fy']             = False     # (N/m); Tangential force (to plane) per unit length at Blade 2, Node 8; 
AeroDyn['B2N9Fy']             = False     # (N/m); Tangential force (to plane) per unit length at Blade 2, Node 9; 
AeroDyn['B3N1Fy']             = False     # (N/m); Tangential force (to plane) per unit length at Blade 3, Node 1; 
AeroDyn['B3N2Fy']             = False     # (N/m); Tangential force (to plane) per unit length at Blade 3, Node 2; 
AeroDyn['B3N3Fy']             = False     # (N/m); Tangential force (to plane) per unit length at Blade 3, Node 3; 
AeroDyn['B3N4Fy']             = False     # (N/m); Tangential force (to plane) per unit length at Blade 3, Node 4; 
AeroDyn['B3N5Fy']             = False     # (N/m); Tangential force (to plane) per unit length at Blade 3, Node 5; 
AeroDyn['B3N6Fy']             = False     # (N/m); Tangential force (to plane) per unit length at Blade 3, Node 6; 
AeroDyn['B3N7Fy']             = False     # (N/m); Tangential force (to plane) per unit length at Blade 3, Node 7; 
AeroDyn['B3N8Fy']             = False     # (N/m); Tangential force (to plane) per unit length at Blade 3, Node 8; 
AeroDyn['B3N9Fy']             = False     # (N/m); Tangential force (to plane) per unit length at Blade 3, Node 9; 
AeroDyn['B1N1Fn']             = False     # (N/m); Normal force (to chord) per unit length at Blade 1, Node 1; 
AeroDyn['B1N2Fn']             = False     # (N/m); Normal force (to chord) per unit length at Blade 1, Node 2; 
AeroDyn['B1N3Fn']             = False     # (N/m); Normal force (to chord) per unit length at Blade 1, Node 3; 
AeroDyn['B1N4Fn']             = False     # (N/m); Normal force (to chord) per unit length at Blade 1, Node 4; 
AeroDyn['B1N5Fn']             = False     # (N/m); Normal force (to chord) per unit length at Blade 1, Node 5; 
AeroDyn['B1N6Fn']             = False     # (N/m); Normal force (to chord) per unit length at Blade 1, Node 6; 
AeroDyn['B1N7Fn']             = False     # (N/m); Normal force (to chord) per unit length at Blade 1, Node 7; 
AeroDyn['B1N8Fn']             = False     # (N/m); Normal force (to chord) per unit length at Blade 1, Node 8; 
AeroDyn['B1N9Fn']             = False     # (N/m); Normal force (to chord) per unit length at Blade 1, Node 9; 
AeroDyn['B2N1Fn']             = False     # (N/m); Normal force (to chord) per unit length at Blade 2, Node 1; 
AeroDyn['B2N2Fn']             = False     # (N/m); Normal force (to chord) per unit length at Blade 2, Node 2; 
AeroDyn['B2N3Fn']             = False     # (N/m); Normal force (to chord) per unit length at Blade 2, Node 3; 
AeroDyn['B2N4Fn']             = False     # (N/m); Normal force (to chord) per unit length at Blade 2, Node 4; 
AeroDyn['B2N5Fn']             = False     # (N/m); Normal force (to chord) per unit length at Blade 2, Node 5; 
AeroDyn['B2N6Fn']             = False     # (N/m); Normal force (to chord) per unit length at Blade 2, Node 6; 
AeroDyn['B2N7Fn']             = False     # (N/m); Normal force (to chord) per unit length at Blade 2, Node 7; 
AeroDyn['B2N8Fn']             = False     # (N/m); Normal force (to chord) per unit length at Blade 2, Node 8; 
AeroDyn['B2N9Fn']             = False     # (N/m); Normal force (to chord) per unit length at Blade 2, Node 9; 
AeroDyn['B3N1Fn']             = False     # (N/m); Normal force (to chord) per unit length at Blade 3, Node 1; 
AeroDyn['B3N2Fn']             = False     # (N/m); Normal force (to chord) per unit length at Blade 3, Node 2; 
AeroDyn['B3N3Fn']             = False     # (N/m); Normal force (to chord) per unit length at Blade 3, Node 3; 
AeroDyn['B3N4Fn']             = False     # (N/m); Normal force (to chord) per unit length at Blade 3, Node 4; 
AeroDyn['B3N5Fn']             = False     # (N/m); Normal force (to chord) per unit length at Blade 3, Node 5; 
AeroDyn['B3N6Fn']             = False     # (N/m); Normal force (to chord) per unit length at Blade 3, Node 6; 
AeroDyn['B3N7Fn']             = False     # (N/m); Normal force (to chord) per unit length at Blade 3, Node 7; 
AeroDyn['B3N8Fn']             = False     # (N/m); Normal force (to chord) per unit length at Blade 3, Node 8; 
AeroDyn['B3N9Fn']             = False     # (N/m); Normal force (to chord) per unit length at Blade 3, Node 9; 
AeroDyn['B1N1Ft']             = False     # (N/m); Tangential force (to chord) per unit length at Blade 1, Node 1; 
AeroDyn['B1N2Ft']             = False     # (N/m); Tangential force (to chord) per unit length at Blade 1, Node 2; 
AeroDyn['B1N3Ft']             = False     # (N/m); Tangential force (to chord) per unit length at Blade 1, Node 3; 
AeroDyn['B1N4Ft']             = False     # (N/m); Tangential force (to chord) per unit length at Blade 1, Node 4; 
AeroDyn['B1N5Ft']             = False     # (N/m); Tangential force (to chord) per unit length at Blade 1, Node 5; 
AeroDyn['B1N6Ft']             = False     # (N/m); Tangential force (to chord) per unit length at Blade 1, Node 6; 
AeroDyn['B1N7Ft']             = False     # (N/m); Tangential force (to chord) per unit length at Blade 1, Node 7; 
AeroDyn['B1N8Ft']             = False     # (N/m); Tangential force (to chord) per unit length at Blade 1, Node 8; 
AeroDyn['B1N9Ft']             = False     # (N/m); Tangential force (to chord) per unit length at Blade 1, Node 9; 
AeroDyn['B2N1Ft']             = False     # (N/m); Tangential force (to chord) per unit length at Blade 2, Node 1; 
AeroDyn['B2N2Ft']             = False     # (N/m); Tangential force (to chord) per unit length at Blade 2, Node 2; 
AeroDyn['B2N3Ft']             = False     # (N/m); Tangential force (to chord) per unit length at Blade 2, Node 3; 
AeroDyn['B2N4Ft']             = False     # (N/m); Tangential force (to chord) per unit length at Blade 2, Node 4; 
AeroDyn['B2N5Ft']             = False     # (N/m); Tangential force (to chord) per unit length at Blade 2, Node 5; 
AeroDyn['B2N6Ft']             = False     # (N/m); Tangential force (to chord) per unit length at Blade 2, Node 6; 
AeroDyn['B2N7Ft']             = False     # (N/m); Tangential force (to chord) per unit length at Blade 2, Node 7; 
AeroDyn['B2N8Ft']             = False     # (N/m); Tangential force (to chord) per unit length at Blade 2, Node 8; 
AeroDyn['B2N9Ft']             = False     # (N/m); Tangential force (to chord) per unit length at Blade 2, Node 9; 
AeroDyn['B3N1Ft']             = False     # (N/m); Tangential force (to chord) per unit length at Blade 3, Node 1; 
AeroDyn['B3N2Ft']             = False     # (N/m); Tangential force (to chord) per unit length at Blade 3, Node 2; 
AeroDyn['B3N3Ft']             = False     # (N/m); Tangential force (to chord) per unit length at Blade 3, Node 3; 
AeroDyn['B3N4Ft']             = False     # (N/m); Tangential force (to chord) per unit length at Blade 3, Node 4; 
AeroDyn['B3N5Ft']             = False     # (N/m); Tangential force (to chord) per unit length at Blade 3, Node 5; 
AeroDyn['B3N6Ft']             = False     # (N/m); Tangential force (to chord) per unit length at Blade 3, Node 6; 
AeroDyn['B3N7Ft']             = False     # (N/m); Tangential force (to chord) per unit length at Blade 3, Node 7; 
AeroDyn['B3N8Ft']             = False     # (N/m); Tangential force (to chord) per unit length at Blade 3, Node 8; 
AeroDyn['B3N9Ft']             = False     # (N/m); Tangential force (to chord) per unit length at Blade 3, Node 9; 
AeroDyn['B1N1Clrnc']          = False     # (m); Tower clearance at Blade 1, Node 1 (based on the absolute distance to the nearest point in the tower from B1N1 minus the local tower radius, in the deflected configuration); please note that this clearance is only approximate because the calculation assumes that the blade is a line with no volume (however, the calculation does use the local tower radius); when B1N1 is above the tower top (or below the tower base), the absolute distance to the tower top (or base) minus the local tower radius, in the deflected configuration, is output; 
AeroDyn['B1N2Clrnc']          = False     # (m); Tower clearance at Blade 1, Node 2 (based on the absolute distance to the nearest point in the tower from B1N2 minus the local tower radius, in the deflected configuration); please note that this clearance is only approximate because the calculation assumes that the blade is a line with no volume (however, the calculation does use the local tower radius); when B1N2 is above the tower top (or below the tower base), the absolute distance to the tower top (or base) minus the local tower radius, in the deflected configuration, is output; 
AeroDyn['B1N3Clrnc']          = False     # (m); Tower clearance at Blade 1, Node 3 (based on the absolute distance to the nearest point in the tower from B1N3 minus the local tower radius, in the deflected configuration); please note that this clearance is only approximate because the calculation assumes that the blade is a line with no volume (however, the calculation does use the local tower radius); when B1N3 is above the tower top (or below the tower base), the absolute distance to the tower top (or base) minus the local tower radius, in the deflected configuration, is output; 
AeroDyn['B1N4Clrnc']          = False     # (m); Tower clearance at Blade 1, Node 4 (based on the absolute distance to the nearest point in the tower from B1N4 minus the local tower radius, in the deflected configuration); please note that this clearance is only approximate because the calculation assumes that the blade is a line with no volume (however, the calculation does use the local tower radius); when B1N4 is above the tower top (or below the tower base), the absolute distance to the tower top (or base) minus the local tower radius, in the deflected configuration, is output; 
AeroDyn['B1N5Clrnc']          = False     # (m); Tower clearance at Blade 1, Node 5 (based on the absolute distance to the nearest point in the tower from B1N5 minus the local tower radius, in the deflected configuration); please note that this clearance is only approximate because the calculation assumes that the blade is a line with no volume (however, the calculation does use the local tower radius); when B1N5 is above the tower top (or below the tower base), the absolute distance to the tower top (or base) minus the local tower radius, in the deflected configuration, is output; 
AeroDyn['B1N6Clrnc']          = False     # (m); Tower clearance at Blade 1, Node 6 (based on the absolute distance to the nearest point in the tower from B1N6 minus the local tower radius, in the deflected configuration); please note that this clearance is only approximate because the calculation assumes that the blade is a line with no volume (however, the calculation does use the local tower radius); when B1N6 is above the tower top (or below the tower base), the absolute distance to the tower top (or base) minus the local tower radius, in the deflected configuration, is output; 
AeroDyn['B1N7Clrnc']          = False     # (m); Tower clearance at Blade 1, Node 7 (based on the absolute distance to the nearest point in the tower from B1N7 minus the local tower radius, in the deflected configuration); please note that this clearance is only approximate because the calculation assumes that the blade is a line with no volume (however, the calculation does use the local tower radius); when B1N7 is above the tower top (or below the tower base), the absolute distance to the tower top (or base) minus the local tower radius, in the deflected configuration, is output; 
AeroDyn['B1N8Clrnc']          = False     # (m); Tower clearance at Blade 1, Node 8 (based on the absolute distance to the nearest point in the tower from B1N8 minus the local tower radius, in the deflected configuration); please note that this clearance is only approximate because the calculation assumes that the blade is a line with no volume (however, the calculation does use the local tower radius); when B1N8 is above the tower top (or below the tower base), the absolute distance to the tower top (or base) minus the local tower radius, in the deflected configuration, is output; 
AeroDyn['B1N9Clrnc']          = False     # (m); Tower clearance at Blade 1, Node 9 (based on the absolute distance to the nearest point in the tower from B1N9 minus the local tower radius, in the deflected configuration); please note that this clearance is only approximate because the calculation assumes that the blade is a line with no volume (however, the calculation does use the local tower radius); when B1N9 is above the tower top (or below the tower base), the absolute distance to the tower top (or base) minus the local tower radius, in the deflected configuration, is output; 
AeroDyn['B2N1Clrnc']          = False     # (m); Tower clearance at Blade 2, Node 1 (based on the absolute distance to the nearest point in the tower from B2N1 minus the local tower radius, in the deflected configuration); please note that this clearance is only approximate because the calculation assumes that the blade is a line with no volume (however, the calculation does use the local tower radius); when B2N1 is above the tower top (or below the tower base), the absolute distance to the tower top (or base) minus the local tower radius, in the deflected configuration, is output; 
AeroDyn['B2N2Clrnc']          = False     # (m); Tower clearance at Blade 2, Node 2 (based on the absolute distance to the nearest point in the tower from B2N2 minus the local tower radius, in the deflected configuration); please note that this clearance is only approximate because the calculation assumes that the blade is a line with no volume (however, the calculation does use the local tower radius); when B2N2 is above the tower top (or below the tower base), the absolute distance to the tower top (or base) minus the local tower radius, in the deflected configuration, is output; 
AeroDyn['B2N3Clrnc']          = False     # (m); Tower clearance at Blade 2, Node 3 (based on the absolute distance to the nearest point in the tower from B2N3 minus the local tower radius, in the deflected configuration); please note that this clearance is only approximate because the calculation assumes that the blade is a line with no volume (however, the calculation does use the local tower radius); when B2N3 is above the tower top (or below the tower base), the absolute distance to the tower top (or base) minus the local tower radius, in the deflected configuration, is output; 
AeroDyn['B2N4Clrnc']          = False     # (m); Tower clearance at Blade 2, Node 4 (based on the absolute distance to the nearest point in the tower from B2N4 minus the local tower radius, in the deflected configuration); please note that this clearance is only approximate because the calculation assumes that the blade is a line with no volume (however, the calculation does use the local tower radius); when B2N4 is above the tower top (or below the tower base), the absolute distance to the tower top (or base) minus the local tower radius, in the deflected configuration, is output; 
AeroDyn['B2N5Clrnc']          = False     # (m); Tower clearance at Blade 2, Node 5 (based on the absolute distance to the nearest point in the tower from B2N5 minus the local tower radius, in the deflected configuration); please note that this clearance is only approximate because the calculation assumes that the blade is a line with no volume (however, the calculation does use the local tower radius); when B2N5 is above the tower top (or below the tower base), the absolute distance to the tower top (or base) minus the local tower radius, in the deflected configuration, is output; 
AeroDyn['B2N6Clrnc']          = False     # (m); Tower clearance at Blade 2, Node 6 (based on the absolute distance to the nearest point in the tower from B2N6 minus the local tower radius, in the deflected configuration); please note that this clearance is only approximate because the calculation assumes that the blade is a line with no volume (however, the calculation does use the local tower radius); when B2N6 is above the tower top (or below the tower base), the absolute distance to the tower top (or base) minus the local tower radius, in the deflected configuration, is output; 
AeroDyn['B2N7Clrnc']          = False     # (m); Tower clearance at Blade 2, Node 7 (based on the absolute distance to the nearest point in the tower from B2N7 minus the local tower radius, in the deflected configuration); please note that this clearance is only approximate because the calculation assumes that the blade is a line with no volume (however, the calculation does use the local tower radius); when B2N7 is above the tower top (or below the tower base), the absolute distance to the tower top (or base) minus the local tower radius, in the deflected configuration, is output; 
AeroDyn['B2N8Clrnc']          = False     # (m); Tower clearance at Blade 2, Node 8 (based on the absolute distance to the nearest point in the tower from B2N8 minus the local tower radius, in the deflected configuration); please note that this clearance is only approximate because the calculation assumes that the blade is a line with no volume (however, the calculation does use the local tower radius); when B2N8 is above the tower top (or below the tower base), the absolute distance to the tower top (or base) minus the local tower radius, in the deflected configuration, is output; 
AeroDyn['B2N9Clrnc']          = False     # (m); Tower clearance at Blade 2, Node 9 (based on the absolute distance to the nearest point in the tower from B2N9 minus the local tower radius, in the deflected configuration); please note that this clearance is only approximate because the calculation assumes that the blade is a line with no volume (however, the calculation does use the local tower radius); when B2N9 is above the tower top (or below the tower base), the absolute distance to the tower top (or base) minus the local tower radius, in the deflected configuration, is output; 
AeroDyn['B3N1Clrnc']          = False     # (m); Tower clearance at Blade 3, Node 1 (based on the absolute distance to the nearest point in the tower from B3N1 minus the local tower radius, in the deflected configuration); please note that this clearance is only approximate because the calculation assumes that the blade is a line with no volume (however, the calculation does use the local tower radius); when B3N1 is above the tower top (or below the tower base), the absolute distance to the tower top (or base) minus the local tower radius, in the deflected configuration, is output; 
AeroDyn['B3N2Clrnc']          = False     # (m); Tower clearance at Blade 3, Node 2 (based on the absolute distance to the nearest point in the tower from B3N2 minus the local tower radius, in the deflected configuration); please note that this clearance is only approximate because the calculation assumes that the blade is a line with no volume (however, the calculation does use the local tower radius); when B3N2 is above the tower top (or below the tower base), the absolute distance to the tower top (or base) minus the local tower radius, in the deflected configuration, is output; 
AeroDyn['B3N3Clrnc']          = False     # (m); Tower clearance at Blade 3, Node 3 (based on the absolute distance to the nearest point in the tower from B3N3 minus the local tower radius, in the deflected configuration); please note that this clearance is only approximate because the calculation assumes that the blade is a line with no volume (however, the calculation does use the local tower radius); when B3N3 is above the tower top (or below the tower base), the absolute distance to the tower top (or base) minus the local tower radius, in the deflected configuration, is output; 
AeroDyn['B3N4Clrnc']          = False     # (m); Tower clearance at Blade 3, Node 4 (based on the absolute distance to the nearest point in the tower from B3N4 minus the local tower radius, in the deflected configuration); please note that this clearance is only approximate because the calculation assumes that the blade is a line with no volume (however, the calculation does use the local tower radius); when B3N4 is above the tower top (or below the tower base), the absolute distance to the tower top (or base) minus the local tower radius, in the deflected configuration, is output; 
AeroDyn['B3N5Clrnc']          = False     # (m); Tower clearance at Blade 3, Node 5 (based on the absolute distance to the nearest point in the tower from B3N5 minus the local tower radius, in the deflected configuration); please note that this clearance is only approximate because the calculation assumes that the blade is a line with no volume (however, the calculation does use the local tower radius); when B3N5 is above the tower top (or below the tower base), the absolute distance to the tower top (or base) minus the local tower radius, in the deflected configuration, is output; 
AeroDyn['B3N6Clrnc']          = False     # (m); Tower clearance at Blade 3, Node 6 (based on the absolute distance to the nearest point in the tower from B3N6 minus the local tower radius, in the deflected configuration); please note that this clearance is only approximate because the calculation assumes that the blade is a line with no volume (however, the calculation does use the local tower radius); when B3N6 is above the tower top (or below the tower base), the absolute distance to the tower top (or base) minus the local tower radius, in the deflected configuration, is output; 
AeroDyn['B3N7Clrnc']          = False     # (m); Tower clearance at Blade 3, Node 7 (based on the absolute distance to the nearest point in the tower from B3N7 minus the local tower radius, in the deflected configuration); please note that this clearance is only approximate because the calculation assumes that the blade is a line with no volume (however, the calculation does use the local tower radius); when B3N7 is above the tower top (or below the tower base), the absolute distance to the tower top (or base) minus the local tower radius, in the deflected configuration, is output; 
AeroDyn['B3N8Clrnc']          = False     # (m); Tower clearance at Blade 3, Node 8 (based on the absolute distance to the nearest point in the tower from B3N8 minus the local tower radius, in the deflected configuration); please note that this clearance is only approximate because the calculation assumes that the blade is a line with no volume (however, the calculation does use the local tower radius); when B3N8 is above the tower top (or below the tower base), the absolute distance to the tower top (or base) minus the local tower radius, in the deflected configuration, is output; 
AeroDyn['B3N9Clrnc']          = False     # (m); Tower clearance at Blade 3, Node 9 (based on the absolute distance to the nearest point in the tower from B3N9 minus the local tower radius, in the deflected configuration); please note that this clearance is only approximate because the calculation assumes that the blade is a line with no volume (however, the calculation does use the local tower radius); when B3N9 is above the tower top (or below the tower base), the absolute distance to the tower top (or base) minus the local tower radius, in the deflected configuration, is output; 
AeroDyn['B1N1Cpmin']          = False     # (-); Pressure coefficient blade 1 node 1; 
AeroDyn['B1N2Cpmin']          = False     # (-); Pressure coefficient blade 1 node 2; 
AeroDyn['B1N3Cpmin']          = False     # (-); Pressure coefficient blade 1 node 3; 
AeroDyn['B1N4Cpmin']          = False     # (-); Pressure coefficient blade 1 node 4; 
AeroDyn['B1N5Cpmin']          = False     # (-); Pressure coefficient blade 1 node 5; 
AeroDyn['B1N6Cpmin']          = False     # (-); Pressure coefficient blade 1 node 6; 
AeroDyn['B1N7Cpmin']          = False     # (-); Pressure coefficient blade 1 node 7; 
AeroDyn['B1N8Cpmin']          = False     # (-); Pressure coefficient blade 1 node 8; 
AeroDyn['B1N9Cpmin']          = False     # (-); Pressure coefficient blade 1 node 9; 
AeroDyn['B2N1Cpmin']          = False     # (-); Pressure coefficient blade 2 node 1; 
AeroDyn['B2N2Cpmin']          = False     # (-); Pressure coefficient blade 2 node 2; 
AeroDyn['B2N3Cpmin']          = False     # (-); Pressure coefficient blade 2 node 3; 
AeroDyn['B2N4Cpmin']          = False     # (-); Pressure coefficient blade 2 node 4; 
AeroDyn['B2N5Cpmin']          = False     # (-); Pressure coefficient blade 2 node 5; 
AeroDyn['B2N6Cpmin']          = False     # (-); Pressure coefficient blade 2 node 6; 
AeroDyn['B2N7Cpmin']          = False     # (-); Pressure coefficient blade 2 node 7; 
AeroDyn['B2N8Cpmin']          = False     # (-); Pressure coefficient blade 2 node 8; 
AeroDyn['B2N9Cpmin']          = False     # (-); Pressure coefficient blade 2 node 9; 
AeroDyn['B3N1Cpmin']          = False     # (-); Pressure coefficient blade 3 node 1; 
AeroDyn['B3N2Cpmin']          = False     # (-); Pressure coefficient blade 3 node 2; 
AeroDyn['B3N3Cpmin']          = False     # (-); Pressure coefficient blade 3 node 3; 
AeroDyn['B3N4Cpmin']          = False     # (-); Pressure coefficient blade 3 node 4; 
AeroDyn['B3N5Cpmin']          = False     # (-); Pressure coefficient blade 3 node 5; 
AeroDyn['B3N6Cpmin']          = False     # (-); Pressure coefficient blade 3 node 6; 
AeroDyn['B3N7Cpmin']          = False     # (-); Pressure coefficient blade 3 node 7; 
AeroDyn['B3N8Cpmin']          = False     # (-); Pressure coefficient blade 3 node 8; 
AeroDyn['B3N9Cpmin']          = False     # (-); Pressure coefficient blade 3 node 9; 
AeroDyn['B1N1SigCr']          = False     # (-); Critical cavitation number blade 1 node 1; 
AeroDyn['B1N2SigCr']          = False     # (-); Critical cavitation number blade 1 node 2; 
AeroDyn['B1N3SigCr']          = False     # (-); Critical cavitation number blade 1 node 3; 
AeroDyn['B1N4SigCr']          = False     # (-); Critical cavitation number blade 1 node 4; 
AeroDyn['B1N5SigCr']          = False     # (-); Critical cavitation number blade 1 node 5; 
AeroDyn['B1N6SigCr']          = False     # (-); Critical cavitation number blade 1 node 6; 
AeroDyn['B1N7SigCr']          = False     # (-); Critical cavitation number blade 1 node 7; 
AeroDyn['B1N8SigCr']          = False     # (-); Critical cavitation number blade 1 node 8; 
AeroDyn['B1N9SigCr']          = False     # (-); Critical cavitation number blade 1 node 9; 
AeroDyn['B2N1SigCr']          = False     # (-); Critical cavitation number blade 2 node 1; 
AeroDyn['B2N2SigCr']          = False     # (-); Critical cavitation number blade 2 node 2; 
AeroDyn['B2N3SigCr']          = False     # (-); Critical cavitation number blade 2 node 3; 
AeroDyn['B2N4SigCr']          = False     # (-); Critical cavitation number blade 2 node 4; 
AeroDyn['B2N5SigCr']          = False     # (-); Critical cavitation number blade 2 node 5; 
AeroDyn['B2N6SigCr']          = False     # (-); Critical cavitation number blade 2 node 6; 
AeroDyn['B2N7SigCr']          = False     # (-); Critical cavitation number blade 2 node 7; 
AeroDyn['B2N8SigCr']          = False     # (-); Critical cavitation number blade 2 node 8; 
AeroDyn['B2N9SigCr']          = False     # (-); Critical cavitation number blade 2 node 9; 
AeroDyn['B3N1SigCr']          = False     # (-); Critical cavitation number blade 3 node 1; 
AeroDyn['B3N2SigCr']          = False     # (-); Critical cavitation number blade 3 node 2; 
AeroDyn['B3N3SigCr']          = False     # (-); Critical cavitation number blade 3 node 3; 
AeroDyn['B3N4SigCr']          = False     # (-); Critical cavitation number blade 3 node 4; 
AeroDyn['B3N5SigCr']          = False     # (-); Critical cavitation number blade 3 node 5; 
AeroDyn['B3N6SigCr']          = False     # (-); Critical cavitation number blade 3 node 6; 
AeroDyn['B3N7SigCr']          = False     # (-); Critical cavitation number blade 3 node 7; 
AeroDyn['B3N8SigCr']          = False     # (-); Critical cavitation number blade 3 node 8; 
AeroDyn['B3N9SigCr']          = False     # (-); Critical cavitation number blade 3 node 9; 
AeroDyn['B1N1SgCav']          = False     # (-); Cavitation number blade 1 node 1; 
AeroDyn['B1N2SgCav']          = False     # (-); Cavitation number blade 1 node 2; 
AeroDyn['B1N3SgCav']          = False     # (-); Cavitation number blade 1 node 3; 
AeroDyn['B1N4SgCav']          = False     # (-); Cavitation number blade 1 node 4; 
AeroDyn['B1N5SgCav']          = False     # (-); Cavitation number blade 1 node 5; 
AeroDyn['B1N6SgCav']          = False     # (-); Cavitation number blade 1 node 6; 
AeroDyn['B1N7SgCav']          = False     # (-); Cavitation number blade 1 node 7; 
AeroDyn['B1N8SgCav']          = False     # (-); Cavitation number blade 1 node 8; 
AeroDyn['B1N9SgCav']          = False     # (-); Cavitation number blade 1 node 9; 
AeroDyn['B2N1SgCav']          = False     # (-); Cavitation number blade 2 node 1; 
AeroDyn['B2N2SgCav']          = False     # (-); Cavitation number blade 2 node 2; 
AeroDyn['B2N3SgCav']          = False     # (-); Cavitation number blade 2 node 3; 
AeroDyn['B2N4SgCav']          = False     # (-); Cavitation number blade 2 node 4; 
AeroDyn['B2N5SgCav']          = False     # (-); Cavitation number blade 2 node 5; 
AeroDyn['B2N6SgCav']          = False     # (-); Cavitation number blade 2 node 6; 
AeroDyn['B2N7SgCav']          = False     # (-); Cavitation number blade 2 node 7; 
AeroDyn['B2N8SgCav']          = False     # (-); Cavitation number blade 2 node 8; 
AeroDyn['B2N9SgCav']          = False     # (-); Cavitation number blade 2 node 9; 
AeroDyn['B3N1SgCav']          = False     # (-); Cavitation number blade 3 node 1; 
AeroDyn['B3N2SgCav']          = False     # (-); Cavitation number blade 3 node 2; 
AeroDyn['B3N3SgCav']          = False     # (-); Cavitation number blade 3 node 3; 
AeroDyn['B3N4SgCav']          = False     # (-); Cavitation number blade 3 node 4; 
AeroDyn['B3N5SgCav']          = False     # (-); Cavitation number blade 3 node 5; 
AeroDyn['B3N6SgCav']          = False     # (-); Cavitation number blade 3 node 6; 
AeroDyn['B3N7SgCav']          = False     # (-); Cavitation number blade 3 node 7; 
AeroDyn['B3N8SgCav']          = False     # (-); Cavitation number blade 3 node 8; 
AeroDyn['B3N9SgCav']          = False     # (-); Cavitation number blade 3 node 9; 
AeroDyn['B1N1Gam']            = False     # (m^2/s); Circulation on blade 1 at node 1; 
AeroDyn['B1N2Gam']            = False     # (m^2/s); Circulation on blade 1 at node 2; 
AeroDyn['B1N3Gam']            = False     # (m^2/s); Circulation on blade 1 at node 3; 
AeroDyn['B1N4Gam']            = False     # (m^2/s); Circulation on blade 1 at node 4; 
AeroDyn['B1N5Gam']            = False     # (m^2/s); Circulation on blade 1 at node 5; 
AeroDyn['B1N6Gam']            = False     # (m^2/s); Circulation on blade 1 at node 6; 
AeroDyn['B1N7Gam']            = False     # (m^2/s); Circulation on blade 1 at node 7; 
AeroDyn['B1N8Gam']            = False     # (m^2/s); Circulation on blade 1 at node 8; 
AeroDyn['B1N9Gam']            = False     # (m^2/s); Circulation on blade 1 at node 9; 
AeroDyn['B2N1Gam']            = False     # (m^2/s); Circulation on blade 2 at node 1; 
AeroDyn['B2N2Gam']            = False     # (m^2/s); Circulation on blade 2 at node 2; 
AeroDyn['B2N3Gam']            = False     # (m^2/s); Circulation on blade 2 at node 3; 
AeroDyn['B2N4Gam']            = False     # (m^2/s); Circulation on blade 2 at node 4; 
AeroDyn['B2N5Gam']            = False     # (m^2/s); Circulation on blade 2 at node 5; 
AeroDyn['B2N6Gam']            = False     # (m^2/s); Circulation on blade 2 at node 6; 
AeroDyn['B2N7Gam']            = False     # (m^2/s); Circulation on blade 2 at node 7; 
AeroDyn['B2N8Gam']            = False     # (m^2/s); Circulation on blade 2 at node 8; 
AeroDyn['B2N9Gam']            = False     # (m^2/s); Circulation on blade 2 at node 9; 
AeroDyn['B3N1Gam']            = False     # (m^2/s); Circulation on blade 3 at node 1; 
AeroDyn['B3N2Gam']            = False     # (m^2/s); Circulation on blade 3 at node 2; 
AeroDyn['B3N3Gam']            = False     # (m^2/s); Circulation on blade 3 at node 3; 
AeroDyn['B3N4Gam']            = False     # (m^2/s); Circulation on blade 3 at node 4; 
AeroDyn['B3N5Gam']            = False     # (m^2/s); Circulation on blade 3 at node 5; 
AeroDyn['B3N6Gam']            = False     # (m^2/s); Circulation on blade 3 at node 6; 
AeroDyn['B3N7Gam']            = False     # (m^2/s); Circulation on blade 3 at node 7; 
AeroDyn['B3N8Gam']            = False     # (m^2/s); Circulation on blade 3 at node 8; 
AeroDyn['B3N9Gam']            = False     # (m^2/s); Circulation on blade 3 at node 9; 
AeroDyn['B1N1Fbn']            = False     # (N/m); Buoyant force normal to chord per unit length at blade 1 node 1; 
AeroDyn['B1N2Fbn']            = False     # (N/m); Buoyant force normal to chord per unit length at blade 1 node 2; 
AeroDyn['B1N3Fbn']            = False     # (N/m); Buoyant force normal to chord per unit length at blade 1 node 3; 
AeroDyn['B1N4Fbn']            = False     # (N/m); Buoyant force normal to chord per unit length at blade 1 node 4; 
AeroDyn['B1N5Fbn']            = False     # (N/m); Buoyant force normal to chord per unit length at blade 1 node 5; 
AeroDyn['B1N6Fbn']            = False     # (N/m); Buoyant force normal to chord per unit length at blade 1 node 6; 
AeroDyn['B1N7Fbn']            = False     # (N/m); Buoyant force normal to chord per unit length at blade 1 node 7; 
AeroDyn['B1N8Fbn']            = False     # (N/m); Buoyant force normal to chord per unit length at blade 1 node 8; 
AeroDyn['B1N9Fbn']            = False     # (N/m); Buoyant force normal to chord per unit length at blade 1 node 9; 
AeroDyn['B2N1Fbn']            = False     # (N/m); Buoyant force normal to chord per unit length at blade 2 node 1; 
AeroDyn['B2N2Fbn']            = False     # (N/m); Buoyant force normal to chord per unit length at blade 2 node 2; 
AeroDyn['B2N3Fbn']            = False     # (N/m); Buoyant force normal to chord per unit length at blade 2 node 3; 
AeroDyn['B2N4Fbn']            = False     # (N/m); Buoyant force normal to chord per unit length at blade 2 node 4; 
AeroDyn['B2N5Fbn']            = False     # (N/m); Buoyant force normal to chord per unit length at blade 2 node 5; 
AeroDyn['B2N6Fbn']            = False     # (N/m); Buoyant force normal to chord per unit length at blade 2 node 6; 
AeroDyn['B2N7Fbn']            = False     # (N/m); Buoyant force normal to chord per unit length at blade 2 node 7; 
AeroDyn['B2N8Fbn']            = False     # (N/m); Buoyant force normal to chord per unit length at blade 2 node 8; 
AeroDyn['B2N9Fbn']            = False     # (N/m); Buoyant force normal to chord per unit length at blade 2 node 9; 
AeroDyn['B3N1Fbn']            = False     # (N/m); Buoyant force normal to chord per unit length at blade 3 node 1; 
AeroDyn['B3N2Fbn']            = False     # (N/m); Buoyant force normal to chord per unit length at blade 3 node 2; 
AeroDyn['B3N3Fbn']            = False     # (N/m); Buoyant force normal to chord per unit length at blade 3 node 3; 
AeroDyn['B3N4Fbn']            = False     # (N/m); Buoyant force normal to chord per unit length at blade 3 node 4; 
AeroDyn['B3N5Fbn']            = False     # (N/m); Buoyant force normal to chord per unit length at blade 3 node 5; 
AeroDyn['B3N6Fbn']            = False     # (N/m); Buoyant force normal to chord per unit length at blade 3 node 6; 
AeroDyn['B3N7Fbn']            = False     # (N/m); Buoyant force normal to chord per unit length at blade 3 node 7; 
AeroDyn['B3N8Fbn']            = False     # (N/m); Buoyant force normal to chord per unit length at blade 3 node 8; 
AeroDyn['B3N9Fbn']            = False     # (N/m); Buoyant force normal to chord per unit length at blade 3 node 9; 
AeroDyn['B1N1Fbt']            = False     # (N/m); Buoyant force tangential to chord per unit length at blade 1 node 1; 
AeroDyn['B1N2Fbt']            = False     # (N/m); Buoyant force tangential to chord per unit length at blade 1 node 2; 
AeroDyn['B1N3Fbt']            = False     # (N/m); Buoyant force tangential to chord per unit length at blade 1 node 3; 
AeroDyn['B1N4Fbt']            = False     # (N/m); Buoyant force tangential to chord per unit length at blade 1 node 4; 
AeroDyn['B1N5Fbt']            = False     # (N/m); Buoyant force tangential to chord per unit length at blade 1 node 5; 
AeroDyn['B1N6Fbt']            = False     # (N/m); Buoyant force tangential to chord per unit length at blade 1 node 6; 
AeroDyn['B1N7Fbt']            = False     # (N/m); Buoyant force tangential to chord per unit length at blade 1 node 7; 
AeroDyn['B1N8Fbt']            = False     # (N/m); Buoyant force tangential to chord per unit length at blade 1 node 8; 
AeroDyn['B1N9Fbt']            = False     # (N/m); Buoyant force tangential to chord per unit length at blade 1 node 9; 
AeroDyn['B2N1Fbt']            = False     # (N/m); Buoyant force tangential to chord per unit length at blade 2 node 1; 
AeroDyn['B2N2Fbt']            = False     # (N/m); Buoyant force tangential to chord per unit length at blade 2 node 2; 
AeroDyn['B2N3Fbt']            = False     # (N/m); Buoyant force tangential to chord per unit length at blade 2 node 3; 
AeroDyn['B2N4Fbt']            = False     # (N/m); Buoyant force tangential to chord per unit length at blade 2 node 4; 
AeroDyn['B2N5Fbt']            = False     # (N/m); Buoyant force tangential to chord per unit length at blade 2 node 5; 
AeroDyn['B2N6Fbt']            = False     # (N/m); Buoyant force tangential to chord per unit length at blade 2 node 6; 
AeroDyn['B2N7Fbt']            = False     # (N/m); Buoyant force tangential to chord per unit length at blade 2 node 7; 
AeroDyn['B2N8Fbt']            = False     # (N/m); Buoyant force tangential to chord per unit length at blade 2 node 8; 
AeroDyn['B2N9Fbt']            = False     # (N/m); Buoyant force tangential to chord per unit length at blade 2 node 9; 
AeroDyn['B3N1Fbt']            = False     # (N/m); Buoyant force tangential to chord per unit length at blade 3 node 1; 
AeroDyn['B3N2Fbt']            = False     # (N/m); Buoyant force tangential to chord per unit length at blade 3 node 2; 
AeroDyn['B3N3Fbt']            = False     # (N/m); Buoyant force tangential to chord per unit length at blade 3 node 3; 
AeroDyn['B3N4Fbt']            = False     # (N/m); Buoyant force tangential to chord per unit length at blade 3 node 4; 
AeroDyn['B3N5Fbt']            = False     # (N/m); Buoyant force tangential to chord per unit length at blade 3 node 5; 
AeroDyn['B3N6Fbt']            = False     # (N/m); Buoyant force tangential to chord per unit length at blade 3 node 6; 
AeroDyn['B3N7Fbt']            = False     # (N/m); Buoyant force tangential to chord per unit length at blade 3 node 7; 
AeroDyn['B3N8Fbt']            = False     # (N/m); Buoyant force tangential to chord per unit length at blade 3 node 8; 
AeroDyn['B3N9Fbt']            = False     # (N/m); Buoyant force tangential to chord per unit length at blade 3 node 9; 
AeroDyn['B1N1Fbs']            = False     # (N/m); Buoyant spanwise force per unit length at blade 1 node 1; 
AeroDyn['B1N2Fbs']            = False     # (N/m); Buoyant spanwise force per unit length at blade 1 node 2; 
AeroDyn['B1N3Fbs']            = False     # (N/m); Buoyant spanwise force per unit length at blade 1 node 3; 
AeroDyn['B1N4Fbs']            = False     # (N/m); Buoyant spanwise force per unit length at blade 1 node 4; 
AeroDyn['B1N5Fbs']            = False     # (N/m); Buoyant spanwise force per unit length at blade 1 node 5; 
AeroDyn['B1N6Fbs']            = False     # (N/m); Buoyant spanwise force per unit length at blade 1 node 6; 
AeroDyn['B1N7Fbs']            = False     # (N/m); Buoyant spanwise force per unit length at blade 1 node 7; 
AeroDyn['B1N8Fbs']            = False     # (N/m); Buoyant spanwise force per unit length at blade 1 node 8; 
AeroDyn['B1N9Fbs']            = False     # (N/m); Buoyant spanwise force per unit length at blade 1 node 9; 
AeroDyn['B2N1Fbs']            = False     # (N/m); Buoyant spanwise force per unit length at blade 2 node 1; 
AeroDyn['B2N2Fbs']            = False     # (N/m); Buoyant spanwise force per unit length at blade 2 node 2; 
AeroDyn['B2N3Fbs']            = False     # (N/m); Buoyant spanwise force per unit length at blade 2 node 3; 
AeroDyn['B2N4Fbs']            = False     # (N/m); Buoyant spanwise force per unit length at blade 2 node 4; 
AeroDyn['B2N5Fbs']            = False     # (N/m); Buoyant spanwise force per unit length at blade 2 node 5; 
AeroDyn['B2N6Fbs']            = False     # (N/m); Buoyant spanwise force per unit length at blade 2 node 6; 
AeroDyn['B2N7Fbs']            = False     # (N/m); Buoyant spanwise force per unit length at blade 2 node 7; 
AeroDyn['B2N8Fbs']            = False     # (N/m); Buoyant spanwise force per unit length at blade 2 node 8; 
AeroDyn['B2N9Fbs']            = False     # (N/m); Buoyant spanwise force per unit length at blade 2 node 9; 
AeroDyn['B3N1Fbs']            = False     # (N/m); Buoyant spanwise force per unit length at blade 3 node 1; 
AeroDyn['B3N2Fbs']            = False     # (N/m); Buoyant spanwise force per unit length at blade 3 node 2; 
AeroDyn['B3N3Fbs']            = False     # (N/m); Buoyant spanwise force per unit length at blade 3 node 3; 
AeroDyn['B3N4Fbs']            = False     # (N/m); Buoyant spanwise force per unit length at blade 3 node 4; 
AeroDyn['B3N5Fbs']            = False     # (N/m); Buoyant spanwise force per unit length at blade 3 node 5; 
AeroDyn['B3N6Fbs']            = False     # (N/m); Buoyant spanwise force per unit length at blade 3 node 6; 
AeroDyn['B3N7Fbs']            = False     # (N/m); Buoyant spanwise force per unit length at blade 3 node 7; 
AeroDyn['B3N8Fbs']            = False     # (N/m); Buoyant spanwise force per unit length at blade 3 node 8; 
AeroDyn['B3N9Fbs']            = False     # (N/m); Buoyant spanwise force per unit length at blade 3 node 9; 
AeroDyn['B1N1Mbn']            = False     # (N-m/m); Buoyant moment normal to chord per unit length at blade 1 node 1; 
AeroDyn['B1N2Mbn']            = False     # (N-m/m); Buoyant moment normal to chord per unit length at blade 1 node 2; 
AeroDyn['B1N3Mbn']            = False     # (N-m/m); Buoyant moment normal to chord per unit length at blade 1 node 3; 
AeroDyn['B1N4Mbn']            = False     # (N-m/m); Buoyant moment normal to chord per unit length at blade 1 node 4; 
AeroDyn['B1N5Mbn']            = False     # (N-m/m); Buoyant moment normal to chord per unit length at blade 1 node 5; 
AeroDyn['B1N6Mbn']            = False     # (N-m/m); Buoyant moment normal to chord per unit length at blade 1 node 6; 
AeroDyn['B1N7Mbn']            = False     # (N-m/m); Buoyant moment normal to chord per unit length at blade 1 node 7; 
AeroDyn['B1N8Mbn']            = False     # (N-m/m); Buoyant moment normal to chord per unit length at blade 1 node 8; 
AeroDyn['B1N9Mbn']            = False     # (N-m/m); Buoyant moment normal to chord per unit length at blade 1 node 9; 
AeroDyn['B2N1Mbn']            = False     # (N-m/m); Buoyant moment normal to chord per unit length at blade 2 node 1; 
AeroDyn['B2N2Mbn']            = False     # (N-m/m); Buoyant moment normal to chord per unit length at blade 2 node 2; 
AeroDyn['B2N3Mbn']            = False     # (N-m/m); Buoyant moment normal to chord per unit length at blade 2 node 3; 
AeroDyn['B2N4Mbn']            = False     # (N-m/m); Buoyant moment normal to chord per unit length at blade 2 node 4; 
AeroDyn['B2N5Mbn']            = False     # (N-m/m); Buoyant moment normal to chord per unit length at blade 2 node 5; 
AeroDyn['B2N6Mbn']            = False     # (N-m/m); Buoyant moment normal to chord per unit length at blade 2 node 6; 
AeroDyn['B2N7Mbn']            = False     # (N-m/m); Buoyant moment normal to chord per unit length at blade 2 node 7; 
AeroDyn['B2N8Mbn']            = False     # (N-m/m); Buoyant moment normal to chord per unit length at blade 2 node 8; 
AeroDyn['B2N9Mbn']            = False     # (N-m/m); Buoyant moment normal to chord per unit length at blade 2 node 9; 
AeroDyn['B3N1Mbn']            = False     # (N-m/m); Buoyant moment normal to chord per unit length at blade 3 node 1; 
AeroDyn['B3N2Mbn']            = False     # (N-m/m); Buoyant moment normal to chord per unit length at blade 3 node 2; 
AeroDyn['B3N3Mbn']            = False     # (N-m/m); Buoyant moment normal to chord per unit length at blade 3 node 3; 
AeroDyn['B3N4Mbn']            = False     # (N-m/m); Buoyant moment normal to chord per unit length at blade 3 node 4; 
AeroDyn['B3N5Mbn']            = False     # (N-m/m); Buoyant moment normal to chord per unit length at blade 3 node 5; 
AeroDyn['B3N6Mbn']            = False     # (N-m/m); Buoyant moment normal to chord per unit length at blade 3 node 6; 
AeroDyn['B3N7Mbn']            = False     # (N-m/m); Buoyant moment normal to chord per unit length at blade 3 node 7; 
AeroDyn['B3N8Mbn']            = False     # (N-m/m); Buoyant moment normal to chord per unit length at blade 3 node 8; 
AeroDyn['B3N9Mbn']            = False     # (N-m/m); Buoyant moment normal to chord per unit length at blade 3 node 9; 
AeroDyn['B1N1Mbt']            = False     # (N-m/m); Buoyant moment tangential to chord per unit length at blade 1 node 1; 
AeroDyn['B1N2Mbt']            = False     # (N-m/m); Buoyant moment tangential to chord per unit length at blade 1 node 2; 
AeroDyn['B1N3Mbt']            = False     # (N-m/m); Buoyant moment tangential to chord per unit length at blade 1 node 3; 
AeroDyn['B1N4Mbt']            = False     # (N-m/m); Buoyant moment tangential to chord per unit length at blade 1 node 4; 
AeroDyn['B1N5Mbt']            = False     # (N-m/m); Buoyant moment tangential to chord per unit length at blade 1 node 5; 
AeroDyn['B1N6Mbt']            = False     # (N-m/m); Buoyant moment tangential to chord per unit length at blade 1 node 6; 
AeroDyn['B1N7Mbt']            = False     # (N-m/m); Buoyant moment tangential to chord per unit length at blade 1 node 7; 
AeroDyn['B1N8Mbt']            = False     # (N-m/m); Buoyant moment tangential to chord per unit length at blade 1 node 8; 
AeroDyn['B1N9Mbt']            = False     # (N-m/m); Buoyant moment tangential to chord per unit length at blade 1 node 9; 
AeroDyn['B2N1Mbt']            = False     # (N-m/m); Buoyant moment tangential to chord per unit length at blade 2 node 1; 
AeroDyn['B2N2Mbt']            = False     # (N-m/m); Buoyant moment tangential to chord per unit length at blade 2 node 2; 
AeroDyn['B2N3Mbt']            = False     # (N-m/m); Buoyant moment tangential to chord per unit length at blade 2 node 3; 
AeroDyn['B2N4Mbt']            = False     # (N-m/m); Buoyant moment tangential to chord per unit length at blade 2 node 4; 
AeroDyn['B2N5Mbt']            = False     # (N-m/m); Buoyant moment tangential to chord per unit length at blade 2 node 5; 
AeroDyn['B2N6Mbt']            = False     # (N-m/m); Buoyant moment tangential to chord per unit length at blade 2 node 6; 
AeroDyn['B2N7Mbt']            = False     # (N-m/m); Buoyant moment tangential to chord per unit length at blade 2 node 7; 
AeroDyn['B2N8Mbt']            = False     # (N-m/m); Buoyant moment tangential to chord per unit length at blade 2 node 8; 
AeroDyn['B2N9Mbt']            = False     # (N-m/m); Buoyant moment tangential to chord per unit length at blade 2 node 9; 
AeroDyn['B3N1Mbt']            = False     # (N-m/m); Buoyant moment tangential to chord per unit length at blade 3 node 1; 
AeroDyn['B3N2Mbt']            = False     # (N-m/m); Buoyant moment tangential to chord per unit length at blade 3 node 2; 
AeroDyn['B3N3Mbt']            = False     # (N-m/m); Buoyant moment tangential to chord per unit length at blade 3 node 3; 
AeroDyn['B3N4Mbt']            = False     # (N-m/m); Buoyant moment tangential to chord per unit length at blade 3 node 4; 
AeroDyn['B3N5Mbt']            = False     # (N-m/m); Buoyant moment tangential to chord per unit length at blade 3 node 5; 
AeroDyn['B3N6Mbt']            = False     # (N-m/m); Buoyant moment tangential to chord per unit length at blade 3 node 6; 
AeroDyn['B3N7Mbt']            = False     # (N-m/m); Buoyant moment tangential to chord per unit length at blade 3 node 7; 
AeroDyn['B3N8Mbt']            = False     # (N-m/m); Buoyant moment tangential to chord per unit length at blade 3 node 8; 
AeroDyn['B3N9Mbt']            = False     # (N-m/m); Buoyant moment tangential to chord per unit length at blade 3 node 9; 
AeroDyn['B1N1Mbs']            = False     # (N-m/m); Buoyant spanwise moment per unit length at blade 1 node 1; 
AeroDyn['B1N2Mbs']            = False     # (N-m/m); Buoyant spanwise moment per unit length at blade 1 node 2; 
AeroDyn['B1N3Mbs']            = False     # (N-m/m); Buoyant spanwise moment per unit length at blade 1 node 3; 
AeroDyn['B1N4Mbs']            = False     # (N-m/m); Buoyant spanwise moment per unit length at blade 1 node 4; 
AeroDyn['B1N5Mbs']            = False     # (N-m/m); Buoyant spanwise moment per unit length at blade 1 node 5; 
AeroDyn['B1N6Mbs']            = False     # (N-m/m); Buoyant spanwise moment per unit length at blade 1 node 6; 
AeroDyn['B1N7Mbs']            = False     # (N-m/m); Buoyant spanwise moment per unit length at blade 1 node 7; 
AeroDyn['B1N8Mbs']            = False     # (N-m/m); Buoyant spanwise moment per unit length at blade 1 node 8; 
AeroDyn['B1N9Mbs']            = False     # (N-m/m); Buoyant spanwise moment per unit length at blade 1 node 9; 
AeroDyn['B2N1Mbs']            = False     # (N-m/m); Buoyant spanwise moment per unit length at blade 2 node 1; 
AeroDyn['B2N2Mbs']            = False     # (N-m/m); Buoyant spanwise moment per unit length at blade 2 node 2; 
AeroDyn['B2N3Mbs']            = False     # (N-m/m); Buoyant spanwise moment per unit length at blade 2 node 3; 
AeroDyn['B2N4Mbs']            = False     # (N-m/m); Buoyant spanwise moment per unit length at blade 2 node 4; 
AeroDyn['B2N5Mbs']            = False     # (N-m/m); Buoyant spanwise moment per unit length at blade 2 node 5; 
AeroDyn['B2N6Mbs']            = False     # (N-m/m); Buoyant spanwise moment per unit length at blade 2 node 6; 
AeroDyn['B2N7Mbs']            = False     # (N-m/m); Buoyant spanwise moment per unit length at blade 2 node 7; 
AeroDyn['B2N8Mbs']            = False     # (N-m/m); Buoyant spanwise moment per unit length at blade 2 node 8; 
AeroDyn['B2N9Mbs']            = False     # (N-m/m); Buoyant spanwise moment per unit length at blade 2 node 9; 
AeroDyn['B3N1Mbs']            = False     # (N-m/m); Buoyant spanwise moment per unit length at blade 3 node 1; 
AeroDyn['B3N2Mbs']            = False     # (N-m/m); Buoyant spanwise moment per unit length at blade 3 node 2; 
AeroDyn['B3N3Mbs']            = False     # (N-m/m); Buoyant spanwise moment per unit length at blade 3 node 3; 
AeroDyn['B3N4Mbs']            = False     # (N-m/m); Buoyant spanwise moment per unit length at blade 3 node 4; 
AeroDyn['B3N5Mbs']            = False     # (N-m/m); Buoyant spanwise moment per unit length at blade 3 node 5; 
AeroDyn['B3N6Mbs']            = False     # (N-m/m); Buoyant spanwise moment per unit length at blade 3 node 6; 
AeroDyn['B3N7Mbs']            = False     # (N-m/m); Buoyant spanwise moment per unit length at blade 3 node 7; 
AeroDyn['B3N8Mbs']            = False     # (N-m/m); Buoyant spanwise moment per unit length at blade 3 node 8; 
AeroDyn['B3N9Mbs']            = False     # (N-m/m); Buoyant spanwise moment per unit length at blade 3 node 9; 

# Rotor
AeroDyn['RtSpeed']            = False     # (rpm); Rotor speed; 
AeroDyn['RtTSR']              = False     # (-); Rotor tip-speed ratio; 
AeroDyn['RtVAvgxh']           = False     # (m/s); Rotor-disk-averaged relative wind velocity (x-component);  the hub coordinate system
AeroDyn['RtVAvgyh']           = False     # (m/s); Rotor-disk-averaged relative wind velocity (y-component);  the hub coordinate system
AeroDyn['RtVAvgzh']           = False     # (m/s); Rotor-disk-averaged relative wind velocity (z-component);  the hub coordinate system
AeroDyn['RtSkew']             = False     # (deg); Rotor inflow-skew angle; 
AeroDyn['RtAeroFxh']          = False     # (N); Total rotor aerodynamic/hydrodynamic and buoyant load (force in x direction);  the hub coordinate system
AeroDyn['RtFldFxh']           = False     # (N); Total rotor aerodynamic/hydrodynamic and buoyant load (force in x direction);  the hub coordinate system
AeroDyn['RtAeroFyh']          = False     # (N); Total rotor aerodynamic/hydrodynamic and buoyant load (force in y direction);  the hub coordinate system
AeroDyn['RtFldFyh']           = False     # (N); Total rotor aerodynamic/hydrodynamic and buoyant load (force in y direction);  the hub coordinate system
AeroDyn['RtAeroFzh']          = False     # (N); Total rotor aerodynamic/hydrodynamic and buoyant load (force in z direction);  the hub coordinate system
AeroDyn['RtFldFzh']           = False     # (N); Total rotor aerodynamic/hydrodynamic and buoyant load (force in z direction);  the hub coordinate system
AeroDyn['RtAeroMxh']          = False     # (N-m); Total rotor aerodynamic/hydrodynamic and buoyant load (moment in x direction);  the hub coordinate system
AeroDyn['RtFldMxh']           = False     # (N-m); Total rotor aerodynamic/hydrodynamic and buoyant load (moment in x direction);  the hub coordinate system
AeroDyn['RtAeroMyh']          = False     # (N-m); Total rotor aerodynamic/hydrodynamic and buoyant load (moment in y direction);  the hub coordinate system
AeroDyn['RtFldMyh']           = False     # (N-m); Total rotor aerodynamic/hydrodynamic and buoyant load (moment in y direction);  the hub coordinate system
AeroDyn['RtAeroMzh']          = False     # (N-m); Total rotor aerodynamic/hydrodynamic and buoyant load (moment in z direction);  the hub coordinate system
AeroDyn['RtFldMzh']           = False     # (N-m); Total rotor aerodynamic/hydrodynamic and buoyant load (moment in z direction);  the hub coordinate system
AeroDyn['RtAeroPwr']          = False     # (W); Rotor aerodynamic/hydrodynamic power; 
AeroDyn['RtFldPwr']           = False     # (W); Rotor aerodynamic/hydrodynamic power; 
AeroDyn['RtArea']             = False     # (m^2); Rotor swept area; 
AeroDyn['RtAeroCp']           = False     # (-); Rotor aerodynamic/hydrodynamic power coefficient; 
AeroDyn['RtFldCp']            = False     # (-); Rotor aerodynamic/hydrodynamic power coefficient; 
AeroDyn['RtAeroCq']           = False     # (-); Rotor aerodynamic/hydrodynamic torque coefficient; 
AeroDyn['RtFldCq']            = False     # (-); Rotor aerodynamic/hydrodynamic torque coefficient; 
AeroDyn['RtAeroCt']           = False     # (-); Rotor aerodynamic/hydrodynamic thrust coefficient; 
AeroDyn['RtFldCt']            = False     # (-); Rotor aerodynamic/hydrodynamic thrust coefficient; 
AeroDyn['DBEMTau1']           = False     # (s); time-constant used in DBEMT; 
AeroDyn['RtAeroFxi']          = False     # (N); Total rotor aerodynamic/hydrodynamic and buoyant load (force in x direction); global coordinate system
AeroDyn['RtFldFxi']           = False     # (N); Total rotor aerodynamic/hydrodynamic and buoyant load (force in x direction); global coordinate system
AeroDyn['RtFldFxg']           = False     # (N); Total rotor aerodynamic/hydrodynamic and buoyant load (force in x direction); global coordinate system
AeroDyn['RtAeroFyi']          = False     # (N); Total rotor aerodynamic/hydrodynamic and buoyant load (force in y direction); global coordinate system
AeroDyn['RtFldFyi']           = False     # (N); Total rotor aerodynamic/hydrodynamic and buoyant load (force in y direction); global coordinate system
AeroDyn['RtFldFyg']           = False     # (N); Total rotor aerodynamic/hydrodynamic and buoyant load (force in y direction); global coordinate system
AeroDyn['RtAeroFzi']          = False     # (N); Total rotor aerodynamic/hydrodynamic and buoyant load (force in z direction); global coordinate system
AeroDyn['RtFldFzi']           = False     # (N); Total rotor aerodynamic/hydrodynamic and buoyant load (force in z direction); global coordinate system
AeroDyn['RtFldFzg']           = False     # (N); Total rotor aerodynamic/hydrodynamic and buoyant load (force in z direction); global coordinate system
AeroDyn['RtAeroMxi']          = False     # (N-m); Total rotor aerodynamic/hydrodynamic and buoyant load (moment in x direction); global coordinate system
AeroDyn['RtFldMxi']           = False     # (N-m); Total rotor aerodynamic/hydrodynamic and buoyant load (moment in x direction); global coordinate system
AeroDyn['RtFldMxg']           = False     # (N-m); Total rotor aerodynamic/hydrodynamic and buoyant load (moment in x direction); global coordinate system
AeroDyn['RtAeroMyi']          = False     # (N-m); Total rotor aerodynamic/hydrodynamic and buoyant load (moment in y direction); global coordinate system
AeroDyn['RtFldMyi']           = False     # (N-m); Total rotor aerodynamic/hydrodynamic and buoyant load (moment in y direction); global coordinate system
AeroDyn['RtFldMyg']           = False     # (N-m); Total rotor aerodynamic/hydrodynamic and buoyant load (moment in y direction); global coordinate system
AeroDyn['RtAeroMzi']          = False     # (N-m); Total rotor aerodynamic/hydrodynamic and buoyant load (moment in z direction); global coordinate system
AeroDyn['RtFldMzi']           = False     # (N-m); Total rotor aerodynamic/hydrodynamic and buoyant load (moment in z direction); global coordinate system
AeroDyn['RtFldMzg']           = False     # (N-m); Total rotor aerodynamic/hydrodynamic and buoyant load (moment in z direction); global coordinate system

# Hub
AeroDyn['HbFbx']              = False     # (N); x-component of buoyant force at hub node;  the hub coordinate system
AeroDyn['HbFby']              = False     # (N); y-component of buoyant force at hub node;  the hub coordinate system
AeroDyn['HbFbz']              = False     # (N); z-component of buoyant force at hub node;  the hub coordinate system
AeroDyn['HbMbx']              = False     # (N-m); x-component of buoyant moment at hub node;  the hub coordinate system
AeroDyn['HbMby']              = False     # (N-m); y-component of buoyant moment at hub node;  the hub coordinate system
AeroDyn['HbMbz']              = False     # (N-m); z-component of buoyant moment at hub node;  the hub coordinate system

# Nacelle
AeroDyn['NcFbx']              = False     # (N); x-component of buoyant force at nacelle node; the nacelle coordinate system
AeroDyn['NcFby']              = False     # (N); y-component of buoyant force at nacelle node; the nacelle coordinate system
AeroDyn['NcFbz']              = False     # (N); z-component of buoyant force at nacelle node; the nacelle coordinate system
AeroDyn['NcMbx']              = False     # (N-m); x-component of buoyant moment at nacelle node; the nacelle coordinate system
AeroDyn['NcMby']              = False     # (N-m); y-component of buoyant moment at nacelle node; the nacelle coordinate system
AeroDyn['NcMbz']              = False     # (N-m); z-component of buoyant moment at nacelle node; the nacelle coordinate system

# TailFin
AeroDyn['TFAlpha']            = False     # (deg); Angle of attack of tailfin; tailfin coordinate system
AeroDyn['TFMach   ']          = False     # (-); Mach number of tailfin flow; tailfin coordinate system
AeroDyn['TFRe   ']            = False     # (-); Reynolds number of tailfin flow; tailfin coordinate system
AeroDyn['TFVrel ']            = False     # (m/s); Orthogonal relative velocity norm at the tailfin reference point; tailfin coordinate system
AeroDyn['TFVundxi']           = False     # (m/s); Undisturbed wind velocity at the tailfin reference point in the inertial system (x-direction); global coordinate system
AeroDyn['TFVundyi']           = False     # (m/s); Undisturbed wind velocity at the tailfin reference point in the inertial system (y-direction); global coordinate system
AeroDyn['TFVundzi']           = False     # (m/s); Undisturbed wind velocity at the tailfin reference point in the inertial system (z-direction); global coordinate system
AeroDyn['TFVindxi']           = False     # (m/s); Induced velocity at the tailfin reference point in the inertial system (x-direction); global coordinate system
AeroDyn['TFVindyi']           = False     # (m/s); Induced velocity at the tailfin reference point in the inertial system (y-direction); global coordinate system
AeroDyn['TFVindzi']           = False     # (m/s); Induced velocity at the tailfin reference point in the inertial system (z-direction); global coordinate system
AeroDyn['TFVrelxi']           = False     # (m/s); Relative velocity at the tailfin reference point in the inertial system (x-direction); global coordinate system
AeroDyn['TFVrelyi']           = False     # (m/s); Relative velocity at the tailfin reference point in the inertial system (y-direction); global coordinate system
AeroDyn['TFVrelzi']           = False     # (m/s); Relative velocity at the tailfin reference point in the inertial system (z-direction); global coordinate system
AeroDyn['TFSTVxi']            = False     # (m/s); Structural velocity at the tailfin reference point in the inertial system (x-direction); global coordinate system
AeroDyn['TFSTVyi']            = False     # (m/s); Structural velocity at the tailfin reference point in the inertial system (y-direction); global coordinate system
AeroDyn['TFSTVzi']            = False     # (m/s); Structural velocity at the tailfin reference point in the inertial system (z-direction); global coordinate system
AeroDyn['TFFxi']              = False     # (N); Force at the tailfin reference point in the inertial system (x-direction); global coordinate system
AeroDyn['TFFyi']              = False     # (N); Force at the tailfin reference point in the inertial system (y-direction); global coordinate system
AeroDyn['TFFzi']              = False     # (N); Force at the tailfin reference point in the inertial system (z-direction); global coordinate system
AeroDyn['TFMxi']              = False     # (N-m); Moment at the tailfin reference point in the inertial system (x-direction); global coordinate system
AeroDyn['TFMyi']              = False     # (N-m); Moment at the tailfin reference point in the inertial system (y-direction); global coordinate system
AeroDyn['TFMzi']              = False     # (N-m); Moment at the tailfin reference point in the inertial system (z-direction); global coordinate system


""" BeamDyn """
BeamDyn = {}

# Reaction Loads
BeamDyn['RootFxr']            = False     # (N); x-component of the root reaction force expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['RootFyr']            = False     # (N); y-component of the root reaction force expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['RootFzr']            = False     # (N); z-component of the root reaction force expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['RootMxr']            = False     # (N-m); x-component of the root reaction moment expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['RootMyr']            = False     # (N-m); y-component of the root reaction moment expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['RootMzr']            = False     # (N-m); z-component of the root reaction moment expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system

# Tip Motions
BeamDyn['TipTDxr']            = False     # (m); Tip translational deflection (relative to the undeflected position) expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['TipTDyr']            = False     # (m); Tip translational deflection (relative to the undeflected position) expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['TipTDzr']            = False     # (m); Tip translational deflection (relative to the undeflected position) expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['TipRDxr']            = False     # (-); Tip angular/rotational deflection Wiener-Milenkovi  parameter (relative to the undeflected orientation) expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['TipRDyr']            = False     # (-); Tip angular/rotational deflection Wiener-Milenkovi  parameter (relative to the undeflected orientation) expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['TipRDzr']            = False     # (-); Tip angular/rotational deflection Wiener-Milenkovi  parameter (relative to the undeflected orientation) expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['TipTVXg']            = False     # (m/s); Tip translational velocities (absolute) expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['TipTVYg']            = False     # (m/s); Tip translational velocities (absolute) expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['TipTVZg']            = False     # (m/s); Tip translational velocities (absolute) expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['TipRVXg']            = False     # (deg/s); Tip angular/rotational velocities (absolute) expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['TipRVYg']            = False     # (deg/s); Tip angular/rotational velocities (absolute) expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['TipRVZg']            = False     # (deg/s); Tip angular/rotational velocities (absolute) expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['TipTAXl']            = False     # (m/s^2); Tip translational accelerations (absolute) expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['TipTAYl']            = False     # (m/s^2); Tip translational accelerations (absolute) expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['TipTAZl']            = False     # (m/s^2); Tip translational accelerations (absolute) expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['TipRAXl']            = False     # (deg/s^2); Tip angular/rotational accelerations (absolute) expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['TipRAYl']            = False     # (deg/s^2); Tip angular/rotational accelerations (absolute) expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['TipRAZl']            = False     # (deg/s^2); Tip angular/rotational accelerations (absolute) expressed in l; l: a floating coordinate system local to the deflected beam

# Sectional Loads
BeamDyn['N1Fxl']              = False     # (N); Sectional force resultants at Node 1 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N1Fyl']              = False     # (N); Sectional force resultants at Node 1 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N1Fzl']              = False     # (N); Sectional force resultants at Node 1 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N2Fxl']              = False     # (N); Sectional force resultants at Node 2 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N2Fyl']              = False     # (N); Sectional force resultants at Node 2 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N2Fzl']              = False     # (N); Sectional force resultants at Node 2 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N3Fxl']              = False     # (N); Sectional force resultants at Node 3 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N3Fyl']              = False     # (N); Sectional force resultants at Node 3 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N3Fzl']              = False     # (N); Sectional force resultants at Node 3 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N4Fxl']              = False     # (N); Sectional force resultants at Node 4 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N4Fyl']              = False     # (N); Sectional force resultants at Node 4 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N4Fzl']              = False     # (N); Sectional force resultants at Node 4 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N5Fxl']              = False     # (N); Sectional force resultants at Node 5 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N5Fyl']              = False     # (N); Sectional force resultants at Node 5 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N5Fzl']              = False     # (N); Sectional force resultants at Node 5 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N6Fxl']              = False     # (N); Sectional force resultants at Node 6 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N6Fyl']              = False     # (N); Sectional force resultants at Node 6 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N6Fzl']              = False     # (N); Sectional force resultants at Node 6 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N7Fxl']              = False     # (N); Sectional force resultants at Node 7 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N7Fyl']              = False     # (N); Sectional force resultants at Node 7 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N7Fzl']              = False     # (N); Sectional force resultants at Node 7 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N8Fxl']              = False     # (N); Sectional force resultants at Node 8 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N8Fyl']              = False     # (N); Sectional force resultants at Node 8 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N8Fzl']              = False     # (N); Sectional force resultants at Node 8 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N9Fxl']              = False     # (N); Sectional force resultants at Node 9 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N9Fyl']              = False     # (N); Sectional force resultants at Node 9 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N9Fzl']              = False     # (N); Sectional force resultants at Node 9 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N1Mxl']              = False     # (N-m); Sectional moment resultants at Node 1 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N1Myl']              = False     # (N-m); Sectional moment resultants at Node 1 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N1Mzl']              = False     # (N-m); Sectional moment resultants at Node 1 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N2Mxl']              = False     # (N-m); Sectional moment resultants at Node 2 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N2Myl']              = False     # (N-m); Sectional moment resultants at Node 2 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N2Mzl']              = False     # (N-m); Sectional moment resultants at Node 2 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N3Mxl']              = False     # (N-m); Sectional moment resultants at Node 3 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N3Myl']              = False     # (N-m); Sectional moment resultants at Node 3 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N3Mzl']              = False     # (N-m); Sectional moment resultants at Node 3 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N4Mxl']              = False     # (N-m); Sectional moment resultants at Node 4 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N4Myl']              = False     # (N-m); Sectional moment resultants at Node 4 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N4Mzl']              = False     # (N-m); Sectional moment resultants at Node 4 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N5Mxl']              = False     # (N-m); Sectional moment resultants at Node 5 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N5Myl']              = False     # (N-m); Sectional moment resultants at Node 5 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N5Mzl']              = False     # (N-m); Sectional moment resultants at Node 5 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N6Mxl']              = False     # (N-m); Sectional moment resultants at Node 6 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N6Myl']              = False     # (N-m); Sectional moment resultants at Node 6 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N6Mzl']              = False     # (N-m); Sectional moment resultants at Node 6 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N7Mxl']              = False     # (N-m); Sectional moment resultants at Node 7 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N7Myl']              = False     # (N-m); Sectional moment resultants at Node 7 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N7Mzl']              = False     # (N-m); Sectional moment resultants at Node 7 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N8Mxl']              = False     # (N-m); Sectional moment resultants at Node 8 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N8Myl']              = False     # (N-m); Sectional moment resultants at Node 8 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N8Mzl']              = False     # (N-m); Sectional moment resultants at Node 8 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N9Mxl']              = False     # (N-m); Sectional moment resultants at Node 9 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N9Myl']              = False     # (N-m); Sectional moment resultants at Node 9 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N9Mzl']              = False     # (N-m); Sectional moment resultants at Node 9 expressed in l; l: a floating coordinate system local to the deflected beam

# Sectional Motions
BeamDyn['N1TDxr']             = False     # (m); Sectional translational deflection (relative to the undeflected position) at Node 1 expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['N1TDyr']             = False     # (m); Sectional translational deflection (relative to the undeflected position) at Node 1 expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['N1TDzr']             = False     # (m); Sectional translational deflection (relative to the undeflected position) at Node 1 expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['N2TDxr']             = False     # (m); Sectional translational deflection (relative to the undeflected position) at Node 2 expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['N2TDyr']             = False     # (m); Sectional translational deflection (relative to the undeflected position) at Node 2 expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['N2TDzr']             = False     # (m); Sectional translational deflection (relative to the undeflected position) at Node 2 expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['N3TDxr']             = False     # (m); Sectional translational deflection (relative to the undeflected position) at Node 3 expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['N3TDyr']             = False     # (m); Sectional translational deflection (relative to the undeflected position) at Node 3 expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['N3TDzr']             = False     # (m); Sectional translational deflection (relative to the undeflected position) at Node 3 expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['N4TDxr']             = False     # (m); Sectional translational deflection (relative to the undeflected position) at Node 4 expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['N4TDyr']             = False     # (m); Sectional translational deflection (relative to the undeflected position) at Node 4 expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['N4TDzr']             = False     # (m); Sectional translational deflection (relative to the undeflected position) at Node 4 expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['N5TDxr']             = False     # (m); Sectional translational deflection (relative to the undeflected position) at Node 5 expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['N5TDyr']             = False     # (m); Sectional translational deflection (relative to the undeflected position) at Node 5 expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['N5TDzr']             = False     # (m); Sectional translational deflection (relative to the undeflected position) at Node 5 expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['N6TDxr']             = False     # (m); Sectional translational deflection (relative to the undeflected position) at Node 6 expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['N6TDyr']             = False     # (m); Sectional translational deflection (relative to the undeflected position) at Node 6 expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['N6TDzr']             = False     # (m); Sectional translational deflection (relative to the undeflected position) at Node 6 expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['N7TDxr']             = False     # (m); Sectional translational deflection (relative to the undeflected position) at Node 7 expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['N7TDyr']             = False     # (m); Sectional translational deflection (relative to the undeflected position) at Node 7 expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['N7TDzr']             = False     # (m); Sectional translational deflection (relative to the undeflected position) at Node 7 expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['N8TDxr']             = False     # (m); Sectional translational deflection (relative to the undeflected position) at Node 8 expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['N8TDyr']             = False     # (m); Sectional translational deflection (relative to the undeflected position) at Node 8 expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['N8TDzr']             = False     # (m); Sectional translational deflection (relative to the undeflected position) at Node 8 expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['N9TDxr']             = False     # (m); Sectional translational deflection (relative to the undeflected position) at Node 9 expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['N9TDyr']             = False     # (m); Sectional translational deflection (relative to the undeflected position) at Node 9 expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['N9TDzr']             = False     # (m); Sectional translational deflection (relative to the undeflected position) at Node 9 expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['N1RDxr']             = False     # (-); Sectional angular/rotational deflection Wiener-Milenkovic parameter (relative to the undeflected orientation) at Node 1 expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['N1RDyr']             = False     # (-); Sectional angular/rotational deflection Wiener-Milenkovic parameter (relative to the undeflected orientation) at Node 1 expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['N1RDzr']             = False     # (-); Sectional angular/rotational deflection Wiener-Milenkovic parameter (relative to the undeflected orientation) at Node 1 expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['N2RDxr']             = False     # (-); Sectional angular/rotational deflection Wiener-Milenkovic parameter (relative to the undeflected orientation) at Node 2 expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['N2RDyr']             = False     # (-); Sectional angular/rotational deflection Wiener-Milenkovic parameter (relative to the undeflected orientation) at Node 2 expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['N2RDzr']             = False     # (-); Sectional angular/rotational deflection Wiener-Milenkovic parameter (relative to the undeflected orientation) at Node 2 expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['N3RDxr']             = False     # (-); Sectional angular/rotational deflection Wiener-Milenkovic parameter (relative to the undeflected orientation) at Node 3 expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['N3RDyr']             = False     # (-); Sectional angular/rotational deflection Wiener-Milenkovic parameter (relative to the undeflected orientation) at Node 3 expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['N3RDzr']             = False     # (-); Sectional angular/rotational deflection Wiener-Milenkovic parameter (relative to the undeflected orientation) at Node 3 expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['N4RDxr']             = False     # (-); Sectional angular/rotational deflection Wiener-Milenkovic parameter (relative to the undeflected orientation) at Node 4 expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['N4RDyr']             = False     # (-); Sectional angular/rotational deflection Wiener-Milenkovic parameter (relative to the undeflected orientation) at Node 4 expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['N4RDzr']             = False     # (-); Sectional angular/rotational deflection Wiener-Milenkovic parameter (relative to the undeflected orientation) at Node 4 expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['N5RDxr']             = False     # (-); Sectional angular/rotational deflection Wiener-Milenkovic parameter (relative to the undeflected orientation) at Node 5 expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['N5RDyr']             = False     # (-); Sectional angular/rotational deflection Wiener-Milenkovic parameter (relative to the undeflected orientation) at Node 5 expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['N5RDzr']             = False     # (-); Sectional angular/rotational deflection Wiener-Milenkovic parameter (relative to the undeflected orientation) at Node 5 expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['N6RDxr']             = False     # (-); Sectional angular/rotational deflection Wiener-Milenkovic parameter (relative to the undeflected orientation) at Node 6 expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['N6RDyr']             = False     # (-); Sectional angular/rotational deflection Wiener-Milenkovic parameter (relative to the undeflected orientation) at Node 6 expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['N6RDzr']             = False     # (-); Sectional angular/rotational deflection Wiener-Milenkovic parameter (relative to the undeflected orientation) at Node 6 expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['N7RDxr']             = False     # (-); Sectional angular/rotational deflection Wiener-Milenkovic parameter (relative to the undeflected orientation) at Node 7 expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['N7RDyr']             = False     # (-); Sectional angular/rotational deflection Wiener-Milenkovic parameter (relative to the undeflected orientation) at Node 7 expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['N7RDzr']             = False     # (-); Sectional angular/rotational deflection Wiener-Milenkovic parameter (relative to the undeflected orientation) at Node 7 expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['N8RDxr']             = False     # (-); Sectional angular/rotational deflection Wiener-Milenkovic parameter (relative to the undeflected orientation) at Node 8 expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['N8RDyr']             = False     # (-); Sectional angular/rotational deflection Wiener-Milenkovic parameter (relative to the undeflected orientation) at Node 8 expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['N8RDzr']             = False     # (-); Sectional angular/rotational deflection Wiener-Milenkovic parameter (relative to the undeflected orientation) at Node 8 expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['N9RDxr']             = False     # (-); Sectional angular/rotational deflection Wiener-Milenkovic parameter (relative to the undeflected orientation) at Node 9 expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['N9RDyr']             = False     # (-); Sectional angular/rotational deflection Wiener-Milenkovic parameter (relative to the undeflected orientation) at Node 9 expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['N9RDzr']             = False     # (-); Sectional angular/rotational deflection Wiener-Milenkovic parameter (relative to the undeflected orientation) at Node 9 expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn['N1TVXg']             = False     # (m/s); Sectional translational velocities (absolute) at Node 1 expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['N1TVYg']             = False     # (m/s); Sectional translational velocities (absolute) at Node 1 expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['N1TVZg']             = False     # (m/s); Sectional translational velocities (absolute) at Node 1 expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['N2TVXg']             = False     # (m/s); Sectional translational velocities (absolute) at Node 2 expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['N2TVYg']             = False     # (m/s); Sectional translational velocities (absolute) at Node 2 expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['N2TVZg']             = False     # (m/s); Sectional translational velocities (absolute) at Node 2 expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['N3TVXg']             = False     # (m/s); Sectional translational velocities (absolute) at Node 3 expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['N3TVYg']             = False     # (m/s); Sectional translational velocities (absolute) at Node 3 expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['N3TVZg']             = False     # (m/s); Sectional translational velocities (absolute) at Node 3 expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['N4TVXg']             = False     # (m/s); Sectional translational velocities (absolute) at Node 4 expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['N4TVYg']             = False     # (m/s); Sectional translational velocities (absolute) at Node 4 expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['N4TVZg']             = False     # (m/s); Sectional translational velocities (absolute) at Node 4 expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['N5TVXg']             = False     # (m/s); Sectional translational velocities (absolute) at Node 5 expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['N5TVYg']             = False     # (m/s); Sectional translational velocities (absolute) at Node 5 expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['N5TVZg']             = False     # (m/s); Sectional translational velocities (absolute) at Node 5 expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['N6TVXg']             = False     # (m/s); Sectional translational velocities (absolute) at Node 6 expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['N6TVYg']             = False     # (m/s); Sectional translational velocities (absolute) at Node 6 expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['N6TVZg']             = False     # (m/s); Sectional translational velocities (absolute) at Node 6 expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['N7TVXg']             = False     # (m/s); Sectional translational velocities (absolute) at Node 7 expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['N7TVYg']             = False     # (m/s); Sectional translational velocities (absolute) at Node 7 expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['N7TVZg']             = False     # (m/s); Sectional translational velocities (absolute) at Node 7 expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['N8TVXg']             = False     # (m/s); Sectional translational velocities (absolute) at Node 8 expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['N8TVYg']             = False     # (m/s); Sectional translational velocities (absolute) at Node 8 expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['N8TVZg']             = False     # (m/s); Sectional translational velocities (absolute) at Node 8 expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['N9TVXg']             = False     # (m/s); Sectional translational velocities (absolute) at Node 9 expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['N9TVYg']             = False     # (m/s); Sectional translational velocities (absolute) at Node 9 expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['N9TVZg']             = False     # (m/s); Sectional translational velocities (absolute) at Node 9 expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['N1RVXg']             = False     # (deg/s); Sectional angular/rotational velocities (absolute) at Node 1 expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['N1RVYg']             = False     # (deg/s); Sectional angular/rotational velocities (absolute) at Node 1 expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['N1RVZg']             = False     # (deg/s); Sectional angular/rotational velocities (absolute) at Node 1 expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['N2RVXg']             = False     # (deg/s); Sectional angular/rotational velocities (absolute) at Node 2 expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['N2RVYg']             = False     # (deg/s); Sectional angular/rotational velocities (absolute) at Node 2 expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['N2RVZg']             = False     # (deg/s); Sectional angular/rotational velocities (absolute) at Node 2 expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['N3RVXg']             = False     # (deg/s); Sectional angular/rotational velocities (absolute) at Node 3 expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['N3RVYg']             = False     # (deg/s); Sectional angular/rotational velocities (absolute) at Node 3 expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['N3RVZg']             = False     # (deg/s); Sectional angular/rotational velocities (absolute) at Node 3 expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['N4RVXg']             = False     # (deg/s); Sectional angular/rotational velocities (absolute) at Node 4 expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['N4RVYg']             = False     # (deg/s); Sectional angular/rotational velocities (absolute) at Node 4 expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['N4RVZg']             = False     # (deg/s); Sectional angular/rotational velocities (absolute) at Node 4 expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['N5RVXg']             = False     # (deg/s); Sectional angular/rotational velocities (absolute) at Node 5 expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['N5RVYg']             = False     # (deg/s); Sectional angular/rotational velocities (absolute) at Node 5 expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['N5RVZg']             = False     # (deg/s); Sectional angular/rotational velocities (absolute) at Node 5 expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['N6RVXg']             = False     # (deg/s); Sectional angular/rotational velocities (absolute) at Node 6 expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['N6RVYg']             = False     # (deg/s); Sectional angular/rotational velocities (absolute) at Node 6 expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['N6RVZg']             = False     # (deg/s); Sectional angular/rotational velocities (absolute) at Node 6 expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['N7RVXg']             = False     # (deg/s); Sectional angular/rotational velocities (absolute) at Node 7 expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['N7RVYg']             = False     # (deg/s); Sectional angular/rotational velocities (absolute) at Node 7 expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['N7RVZg']             = False     # (deg/s); Sectional angular/rotational velocities (absolute) at Node 7 expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['N8RVXg']             = False     # (deg/s); Sectional angular/rotational velocities (absolute) at Node 8 expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['N8RVYg']             = False     # (deg/s); Sectional angular/rotational velocities (absolute) at Node 8 expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['N8RVZg']             = False     # (deg/s); Sectional angular/rotational velocities (absolute) at Node 8 expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['N9RVXg']             = False     # (deg/s); Sectional angular/rotational velocities (absolute) at Node 9 expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['N9RVYg']             = False     # (deg/s); Sectional angular/rotational velocities (absolute) at Node 9 expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['N9RVZg']             = False     # (deg/s); Sectional angular/rotational velocities (absolute) at Node 9 expressed in g; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system
BeamDyn['N1TAXl']             = False     # (m/s^2); Sectional translational accelerations (absolute) at Node 1 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N1TAYl']             = False     # (m/s^2); Sectional translational accelerations (absolute) at Node 1 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N1TAZl']             = False     # (m/s^2); Sectional translational accelerations (absolute) at Node 1 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N2TAXl']             = False     # (m/s^2); Sectional translational accelerations (absolute) at Node 2 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N2TAYl']             = False     # (m/s^2); Sectional translational accelerations (absolute) at Node 2 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N2TAZl']             = False     # (m/s^2); Sectional translational accelerations (absolute) at Node 2 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N3TAXl']             = False     # (m/s^2); Sectional translational accelerations (absolute) at Node 3 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N3TAYl']             = False     # (m/s^2); Sectional translational accelerations (absolute) at Node 3 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N3TAZl']             = False     # (m/s^2); Sectional translational accelerations (absolute) at Node 3 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N4TAXl']             = False     # (m/s^2); Sectional translational accelerations (absolute) at Node 4 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N4TAYl']             = False     # (m/s^2); Sectional translational accelerations (absolute) at Node 4 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N4TAZl']             = False     # (m/s^2); Sectional translational accelerations (absolute) at Node 4 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N5TAXl']             = False     # (m/s^2); Sectional translational accelerations (absolute) at Node 5 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N5TAYl']             = False     # (m/s^2); Sectional translational accelerations (absolute) at Node 5 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N5TAZl']             = False     # (m/s^2); Sectional translational accelerations (absolute) at Node 5 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N6TAXl']             = False     # (m/s^2); Sectional translational accelerations (absolute) at Node 6 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N6TAYl']             = False     # (m/s^2); Sectional translational accelerations (absolute) at Node 6 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N6TAZl']             = False     # (m/s^2); Sectional translational accelerations (absolute) at Node 6 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N7TAXl']             = False     # (m/s^2); Sectional translational accelerations (absolute) at Node 7 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N7TAYl']             = False     # (m/s^2); Sectional translational accelerations (absolute) at Node 7 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N7TAZl']             = False     # (m/s^2); Sectional translational accelerations (absolute) at Node 7 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N8TAXl']             = False     # (m/s^2); Sectional translational accelerations (absolute) at Node 8 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N8TAYl']             = False     # (m/s^2); Sectional translational accelerations (absolute) at Node 8 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N8TAZl']             = False     # (m/s^2); Sectional translational accelerations (absolute) at Node 8 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N9TAXl']             = False     # (m/s^2); Sectional translational accelerations (absolute) at Node 9 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N9TAYl']             = False     # (m/s^2); Sectional translational accelerations (absolute) at Node 9 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N9TAZl']             = False     # (m/s^2); Sectional translational accelerations (absolute) at Node 9 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N1RAXl']             = False     # (deg/s^2); Sectional angular/rotational accelerations (absolute) at Node 1 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N1RAYl']             = False     # (deg/s^2); Sectional angular/rotational accelerations (absolute) at Node 1 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N1RAZl']             = False     # (deg/s^2); Sectional angular/rotational accelerations (absolute) at Node 1 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N2RAXl']             = False     # (deg/s^2); Sectional angular/rotational accelerations (absolute) at Node 2 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N2RAYl']             = False     # (deg/s^2); Sectional angular/rotational accelerations (absolute) at Node 2 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N2RAZl']             = False     # (deg/s^2); Sectional angular/rotational accelerations (absolute) at Node 2 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N3RAXl']             = False     # (deg/s^2); Sectional angular/rotational accelerations (absolute) at Node 3 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N3RAYl']             = False     # (deg/s^2); Sectional angular/rotational accelerations (absolute) at Node 3 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N3RAZl']             = False     # (deg/s^2); Sectional angular/rotational accelerations (absolute) at Node 3 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N4RAXl']             = False     # (deg/s^2); Sectional angular/rotational accelerations (absolute) at Node 4 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N4RAYl']             = False     # (deg/s^2); Sectional angular/rotational accelerations (absolute) at Node 4 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N4RAZl']             = False     # (deg/s^2); Sectional angular/rotational accelerations (absolute) at Node 4 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N5RAXl']             = False     # (deg/s^2); Sectional angular/rotational accelerations (absolute) at Node 5 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N5RAYl']             = False     # (deg/s^2); Sectional angular/rotational accelerations (absolute) at Node 5 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N5RAZl']             = False     # (deg/s^2); Sectional angular/rotational accelerations (absolute) at Node 5 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N6RAXl']             = False     # (deg/s^2); Sectional angular/rotational accelerations (absolute) at Node 6 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N6RAYl']             = False     # (deg/s^2); Sectional angular/rotational accelerations (absolute) at Node 6 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N6RAZl']             = False     # (deg/s^2); Sectional angular/rotational accelerations (absolute) at Node 6 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N7RAXl']             = False     # (deg/s^2); Sectional angular/rotational accelerations (absolute) at Node 7 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N7RAYl']             = False     # (deg/s^2); Sectional angular/rotational accelerations (absolute) at Node 7 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N7RAZl']             = False     # (deg/s^2); Sectional angular/rotational accelerations (absolute) at Node 7 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N8RAXl']             = False     # (deg/s^2); Sectional angular/rotational accelerations (absolute) at Node 8 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N8RAYl']             = False     # (deg/s^2); Sectional angular/rotational accelerations (absolute) at Node 8 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N8RAZl']             = False     # (deg/s^2); Sectional angular/rotational accelerations (absolute) at Node 8 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N9RAXl']             = False     # (deg/s^2); Sectional angular/rotational accelerations (absolute) at Node 9 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N9RAYl']             = False     # (deg/s^2); Sectional angular/rotational accelerations (absolute) at Node 9 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N9RAZl']             = False     # (deg/s^2); Sectional angular/rotational accelerations (absolute) at Node 9 expressed in l; l: a floating coordinate system local to the deflected beam

# Applied Loads
BeamDyn['N1PFxl']             = False     # (N); Applied point forces at Node 1 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N1PFyl']             = False     # (N); Applied point forces at Node 1 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N1PFzl']             = False     # (N); Applied point forces at Node 1 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N2PFxl']             = False     # (N); Applied point forces at Node 2 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N2PFyl']             = False     # (N); Applied point forces at Node 2 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N2PFzl']             = False     # (N); Applied point forces at Node 2 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N3PFxl']             = False     # (N); Applied point forces at Node 3 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N3PFyl']             = False     # (N); Applied point forces at Node 3 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N3PFzl']             = False     # (N); Applied point forces at Node 3 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N4PFxl']             = False     # (N); Applied point forces at Node 4 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N4PFyl']             = False     # (N); Applied point forces at Node 4 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N4PFzl']             = False     # (N); Applied point forces at Node 4 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N5PFxl']             = False     # (N); Applied point forces at Node 5 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N5PFyl']             = False     # (N); Applied point forces at Node 5 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N5PFzl']             = False     # (N); Applied point forces at Node 5 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N6PFxl']             = False     # (N); Applied point forces at Node 6 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N6PFyl']             = False     # (N); Applied point forces at Node 6 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N6PFzl']             = False     # (N); Applied point forces at Node 6 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N7PFxl']             = False     # (N); Applied point forces at Node 7 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N7PFyl']             = False     # (N); Applied point forces at Node 7 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N7PFzl']             = False     # (N); Applied point forces at Node 7 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N8PFxl']             = False     # (N); Applied point forces at Node 8 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N8PFyl']             = False     # (N); Applied point forces at Node 8 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N8PFzl']             = False     # (N); Applied point forces at Node 8 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N9PFxl']             = False     # (N); Applied point forces at Node 9 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N9PFyl']             = False     # (N); Applied point forces at Node 9 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N9PFzl']             = False     # (N); Applied point forces at Node 9 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N1PMxl']             = False     # (N-m); Applied point moments at Node 1 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N1PMyl']             = False     # (N-m); Applied point moments at Node 1 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N1PMzl']             = False     # (N-m); Applied point moments at Node 1 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N2PMxl']             = False     # (N-m); Applied point moments at Node 2 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N2PMyl']             = False     # (N-m); Applied point moments at Node 2 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N2PMzl']             = False     # (N-m); Applied point moments at Node 2 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N3PMxl']             = False     # (N-m); Applied point moments at Node 3 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N3PMyl']             = False     # (N-m); Applied point moments at Node 3 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N3PMzl']             = False     # (N-m); Applied point moments at Node 3 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N4PMxl']             = False     # (N-m); Applied point moments at Node 4 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N4PMyl']             = False     # (N-m); Applied point moments at Node 4 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N4PMzl']             = False     # (N-m); Applied point moments at Node 4 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N5PMxl']             = False     # (N-m); Applied point moments at Node 5 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N5PMyl']             = False     # (N-m); Applied point moments at Node 5 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N5PMzl']             = False     # (N-m); Applied point moments at Node 5 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N6PMxl']             = False     # (N-m); Applied point moments at Node 6 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N6PMyl']             = False     # (N-m); Applied point moments at Node 6 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N6PMzl']             = False     # (N-m); Applied point moments at Node 6 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N7PMxl']             = False     # (N-m); Applied point moments at Node 7 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N7PMyl']             = False     # (N-m); Applied point moments at Node 7 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N7PMzl']             = False     # (N-m); Applied point moments at Node 7 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N8PMxl']             = False     # (N-m); Applied point moments at Node 8 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N8PMyl']             = False     # (N-m); Applied point moments at Node 8 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N8PMzl']             = False     # (N-m); Applied point moments at Node 8 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N9PMxl']             = False     # (N-m); Applied point moments at Node 9 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N9PMyl']             = False     # (N-m); Applied point moments at Node 9 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N9PMzl']             = False     # (N-m); Applied point moments at Node 9 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N1DFxl']             = False     # (N/m); Applied distributed forces at Node 1 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N1DFyl']             = False     # (N/m); Applied distributed forces at Node 1 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N1DFzl']             = False     # (N/m); Applied distributed forces at Node 1 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N2DFxl']             = False     # (N/m); Applied distributed forces at Node 2 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N2DFyl']             = False     # (N/m); Applied distributed forces at Node 2 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N2DFzl']             = False     # (N/m); Applied distributed forces at Node 2 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N3DFxl']             = False     # (N/m); Applied distributed forces at Node 3 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N3DFyl']             = False     # (N/m); Applied distributed forces at Node 3 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N3DFzl']             = False     # (N/m); Applied distributed forces at Node 3 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N4DFxl']             = False     # (N/m); Applied distributed forces at Node 4 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N4DFyl']             = False     # (N/m); Applied distributed forces at Node 4 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N4DFzl']             = False     # (N/m); Applied distributed forces at Node 4 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N5DFxl']             = False     # (N/m); Applied distributed forces at Node 5 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N5DFyl']             = False     # (N/m); Applied distributed forces at Node 5 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N5DFzl']             = False     # (N/m); Applied distributed forces at Node 5 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N6DFxl']             = False     # (N/m); Applied distributed forces at Node 6 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N6DFyl']             = False     # (N/m); Applied distributed forces at Node 6 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N6DFzl']             = False     # (N/m); Applied distributed forces at Node 6 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N7DFxl']             = False     # (N/m); Applied distributed forces at Node 7 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N7DFyl']             = False     # (N/m); Applied distributed forces at Node 7 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N7DFzl']             = False     # (N/m); Applied distributed forces at Node 7 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N8DFxl']             = False     # (N/m); Applied distributed forces at Node 8 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N8DFyl']             = False     # (N/m); Applied distributed forces at Node 8 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N8DFzl']             = False     # (N/m); Applied distributed forces at Node 8 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N9DFxl']             = False     # (N/m); Applied distributed forces at Node 9 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N9DFyl']             = False     # (N/m); Applied distributed forces at Node 9 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N9DFzl']             = False     # (N/m); Applied distributed forces at Node 9 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N1DMxl']             = False     # (N-m/m); Applied distributed moments at Node 1 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N1DMyl']             = False     # (N-m/m); Applied distributed moments at Node 1 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N1DMzl']             = False     # (N-m/m); Applied distributed moments at Node 1 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N2DMxl']             = False     # (N-m/m); Applied distributed moments at Node 2 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N2DMyl']             = False     # (N-m/m); Applied distributed moments at Node 2 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N2DMzl']             = False     # (N-m/m); Applied distributed moments at Node 2 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N3DMxl']             = False     # (N-m/m); Applied distributed moments at Node 3 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N3DMyl']             = False     # (N-m/m); Applied distributed moments at Node 3 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N3DMzl']             = False     # (N-m/m); Applied distributed moments at Node 3 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N4DMxl']             = False     # (N-m/m); Applied distributed moments at Node 4 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N4DMyl']             = False     # (N-m/m); Applied distributed moments at Node 4 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N4DMzl']             = False     # (N-m/m); Applied distributed moments at Node 4 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N5DMxl']             = False     # (N-m/m); Applied distributed moments at Node 5 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N5DMyl']             = False     # (N-m/m); Applied distributed moments at Node 5 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N5DMzl']             = False     # (N-m/m); Applied distributed moments at Node 5 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N6DMxl']             = False     # (N-m/m); Applied distributed moments at Node 6 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N6DMyl']             = False     # (N-m/m); Applied distributed moments at Node 6 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N6DMzl']             = False     # (N-m/m); Applied distributed moments at Node 6 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N7DMxl']             = False     # (N-m/m); Applied distributed moments at Node 7 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N7DMyl']             = False     # (N-m/m); Applied distributed moments at Node 7 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N7DMzl']             = False     # (N-m/m); Applied distributed moments at Node 7 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N8DMxl']             = False     # (N-m/m); Applied distributed moments at Node 8 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N8DMyl']             = False     # (N-m/m); Applied distributed moments at Node 8 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N8DMzl']             = False     # (N-m/m); Applied distributed moments at Node 8 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N9DMxl']             = False     # (N-m/m); Applied distributed moments at Node 9 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N9DMyl']             = False     # (N-m/m); Applied distributed moments at Node 9 expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn['N9DMzl']             = False     # (N-m/m); Applied distributed moments at Node 9 expressed in l; l: a floating coordinate system local to the deflected beam

# Pitch Actuator
BeamDyn['PAngInp']            = False     # (deg); Pitch angle input; 
BeamDyn['PAngAct']            = False     # (deg); Actual pitch angle ; 
BeamDyn['PRatAct']            = False     # (deg/s); Actual pitch rate; 
BeamDyn['PAccAct']            = False     # (deg/s^2); Actual pitch acceleration; 


""" ElastoDyn """
ElastoDyn = {}

# Blade 1 Tip Motions
ElastoDyn['TipDxc1']          = True      # (m); Blade 1 out-of-plane tip deflection (relative to the undeflected position); Directed along the xc1-axis
ElastoDyn['OoPDefl1']         = False     # (m); Blade 1 out-of-plane tip deflection (relative to the undeflected position); Directed along the xc1-axis
ElastoDyn['TipDyc1']          = True      # (m); Blade 1 in-plane tip deflection (relative to the undeflected position); Directed along the yc1-axis
ElastoDyn['IPDefl1']          = False     # (m); Blade 1 in-plane tip deflection (relative to the undeflected position); Directed along the yc1-axis
ElastoDyn['TipDzc1']          = True      # (m); Blade 1 axial tip deflection (relative to the undeflected position); Directed along the zc1- and zb1-axes
ElastoDyn['TipDzb1']          = True      # (m); Blade 1 axial tip deflection (relative to the undeflected position); Directed along the zc1- and zb1-axes
ElastoDyn['TipDxb1']          = True      # (m); Blade 1 flapwise tip deflection (relative to the undeflected position); Directed along the xb1-axis
ElastoDyn['TipDyb1']          = True      # (m); Blade 1 edgewise tip deflection (relative to the undeflected position); Directed along the yb1-axis
ElastoDyn['TipALxb1']         = False     # (m/s^2); Blade 1 local flapwise tip acceleration (absolute); Directed along the local xb1-axis
ElastoDyn['TipALyb1']         = False     # (m/s^2); Blade 1 local edgewise tip acceleration (absolute); Directed along the local yb1-axis
ElastoDyn['TipALzb1']         = False     # (m/s^2); Blade 1 local axial tip acceleration (absolute); Directed along the local zb1-axis
ElastoDyn['TipALgxb1']        = False     # (m/s^2); Blade 1 local flapwise tip acceleration (relative to g); Directed along the local xb1-axis
ElastoDyn['TipALgyb1']        = False     # (m/s^2); Blade 1 local edgewise tip acceleration (relative to g); Directed along the local yb1-axis
ElastoDyn['TipALgzb1']        = False     # (m/s^2); Blade 1 local axial tip acceleration (relative to g); Directed along the local zb1-axis
ElastoDyn['TipRDxb1']         = False     # (deg); Blade 1 roll (angular/rotational) tip deflection (relative to the undeflected position). In ADAMS, it is output as an Euler angle computed as the 3rd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the xb1-axis
ElastoDyn['RollDefl1']        = False     # (deg); Blade 1 roll (angular/rotational) tip deflection (relative to the undeflected position). In ADAMS, it is output as an Euler angle computed as the 3rd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the xb1-axis
ElastoDyn['TipRDyb1']         = False     # (deg); Blade 1 pitch (angular/rotational) tip deflection (relative to the undeflected position). In ADAMS, it is output as an Euler angle computed as the 2nd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the yb1-axis
ElastoDyn['PtchDefl1']        = False     # (deg); Blade 1 pitch (angular/rotational) tip deflection (relative to the undeflected position). In ADAMS, it is output as an Euler angle computed as the 2nd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the yb1-axis
ElastoDyn['TipRDzc1']         = False     # (deg); Blade 1 torsional tip deflection (relative to the undeflected position). This output will always be zero for FAST simulation results. Use it for examining blade torsional deflections of ADAMS simulations run using ADAMS datasets created using the FAST-to-ADAMS preprocessor. In ADAMS, it is output as an Euler angle computed as the 1st rotation in the yaw-pitch-roll rotation sequence.  Please note that this output uses the opposite of the sign convention used for blade pitch angles.; About the zc1- and zb1-axes
ElastoDyn['TipRDzb1']         = False     # (deg); Blade 1 torsional tip deflection (relative to the undeflected position). This output will always be zero for FAST simulation results. Use it for examining blade torsional deflections of ADAMS simulations run using ADAMS datasets created using the FAST-to-ADAMS preprocessor. In ADAMS, it is output as an Euler angle computed as the 1st rotation in the yaw-pitch-roll rotation sequence.  Please note that this output uses the opposite of the sign convention used for blade pitch angles.; About the zc1- and zb1-axes
ElastoDyn['TwstDefl1']        = False     # (deg); Blade 1 torsional tip deflection (relative to the undeflected position). This output will always be zero for FAST simulation results. Use it for examining blade torsional deflections of ADAMS simulations run using ADAMS datasets created using the FAST-to-ADAMS preprocessor. In ADAMS, it is output as an Euler angle computed as the 1st rotation in the yaw-pitch-roll rotation sequence.  Please note that this output uses the opposite of the sign convention used for blade pitch angles.; About the zc1- and zb1-axes
ElastoDyn['TipClrnc1']        = False     # (m); Blade 1 tip-to-tower clearance estimate. This is computed as the perpendicular distance from the yaw axis to the tip of blade 1 when the blade tip is below the yaw bearing. When the tip of blade 1 is above the yaw bearing, it is computed as the absolute distance from the yaw bearing to the blade tip. Please note that you should reduce this value by the tower radius to obtain the actual tower clearance.; N/A
ElastoDyn['TwrClrnc1']        = False     # (m); Blade 1 tip-to-tower clearance estimate. This is computed as the perpendicular distance from the yaw axis to the tip of blade 1 when the blade tip is below the yaw bearing. When the tip of blade 1 is above the yaw bearing, it is computed as the absolute distance from the yaw bearing to the blade tip. Please note that you should reduce this value by the tower radius to obtain the actual tower clearance.; N/A
ElastoDyn['Tip2Twr1']         = False     # (m); Blade 1 tip-to-tower clearance estimate. This is computed as the perpendicular distance from the yaw axis to the tip of blade 1 when the blade tip is below the yaw bearing. When the tip of blade 1 is above the yaw bearing, it is computed as the absolute distance from the yaw bearing to the blade tip. Please note that you should reduce this value by the tower radius to obtain the actual tower clearance.; N/A

# Blade 2 Tip Motions
ElastoDyn['TipDxc2']          = True      # (m); Blade 2 out-of-plane tip deflection (relative to the pitch axis); Directed along the xc2-axis
ElastoDyn['OoPDefl2']         = False     # (m); Blade 2 out-of-plane tip deflection (relative to the pitch axis); Directed along the xc2-axis
ElastoDyn['TipDyc2']          = True      # (m); Blade 2 in-plane tip deflection (relative to the pitch axis); Directed along the yc2-axis
ElastoDyn['IPDefl2']          = False     # (m); Blade 2 in-plane tip deflection (relative to the pitch axis); Directed along the yc2-axis
ElastoDyn['TipDzc2']          = True      # (m); Blade 2 axial tip deflection (relative to the pitch axis); Directed along the zc2- and zb2-axes
ElastoDyn['TipDzb2']          = True      # (m); Blade 2 axial tip deflection (relative to the pitch axis); Directed along the zc2- and zb2-axes
ElastoDyn['TipDxb2']          = True      # (m); Blade 2 flapwise tip deflection (relative to the pitch axis); Directed along the xb2-axis
ElastoDyn['TipDyb2']          = True      # (m); Blade 2 edgewise tip deflection (relative to the pitch axis); Directed along the yb2-axis
ElastoDyn['TipALxb2']         = False     # (m/s^2); Blade 2 local flapwise tip acceleration (absolute); Directed along the local xb2-axis
ElastoDyn['TipALyb2']         = False     # (m/s^2); Blade 2 local edgewise tip acceleration (absolute); Directed along the local yb2-axis
ElastoDyn['TipALzb2']         = False     # (m/s^2); Blade 2 local axial tip acceleration (absolute); Directed along the local zb2-axis
ElastoDyn['TipALgxb2']        = False     # (m/s^2); Blade 2 local flapwise tip acceleration (relative to g); Directed along the local xb2-axis
ElastoDyn['TipALgyb2']        = False     # (m/s^2); Blade 2 local edgewise tip acceleration (relative to g); Directed along the local yb2-axis
ElastoDyn['TipALgzb2']        = False     # (m/s^2); Blade 2 local axial tip acceleration (relative to g); Directed along the local zb2-axis
ElastoDyn['TipRDxb2']         = False     # (deg); Blade 2 roll (angular/rotational) tip deflection (relative to the undeflected position). In ADAMS, it is output as an Euler angle computed as the 3rd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the xb2-axis
ElastoDyn['RollDefl2']        = False     # (deg); Blade 2 roll (angular/rotational) tip deflection (relative to the undeflected position). In ADAMS, it is output as an Euler angle computed as the 3rd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the xb2-axis
ElastoDyn['TipRDyb2']         = False     # (deg); Blade 2 pitch (angular/rotational) tip deflection (relative to the undeflected position). In ADAMS, it is output as an Euler angle computed as the 2nd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the yb2-axis
ElastoDyn['PtchDefl2']        = False     # (deg); Blade 2 pitch (angular/rotational) tip deflection (relative to the undeflected position). In ADAMS, it is output as an Euler angle computed as the 2nd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the yb2-axis
ElastoDyn['TipRDzc2']         = False     # (deg); Blade 2 torsional (angular/rotational) tip deflection (relative to the undeflected position). This output will always be zero for FAST simulation results. Use it for examining blade torsional deflections of ADAMS simulations run using ADAMS datasets created using the FAST-to-ADAMS preprocessor. In ADAMS, it is output as an Euler angle computed as the 1st rotation in the yaw-pitch-roll rotation sequence.  Please note that this output uses the opposite of the sign convention used for blade pitch angles.; About the zc2- and zb2-axes
ElastoDyn['TipRDzb2']         = False     # (deg); Blade 2 torsional (angular/rotational) tip deflection (relative to the undeflected position). This output will always be zero for FAST simulation results. Use it for examining blade torsional deflections of ADAMS simulations run using ADAMS datasets created using the FAST-to-ADAMS preprocessor. In ADAMS, it is output as an Euler angle computed as the 1st rotation in the yaw-pitch-roll rotation sequence.  Please note that this output uses the opposite of the sign convention used for blade pitch angles.; About the zc2- and zb2-axes
ElastoDyn['TwstDefl2']        = False     # (deg); Blade 2 torsional (angular/rotational) tip deflection (relative to the undeflected position). This output will always be zero for FAST simulation results. Use it for examining blade torsional deflections of ADAMS simulations run using ADAMS datasets created using the FAST-to-ADAMS preprocessor. In ADAMS, it is output as an Euler angle computed as the 1st rotation in the yaw-pitch-roll rotation sequence.  Please note that this output uses the opposite of the sign convention used for blade pitch angles.; About the zc2- and zb2-axes
ElastoDyn['TipClrnc2']        = False     # (m); Blade 2 tip-to-tower clearance estimate. This is computed as the perpendicular distance from the yaw axis to the tip of blade 1 when the blade tip is below the yaw bearing. When the tip of blade 1 is above the yaw bearing, it is computed as the absolute distance from the yaw bearing to the blade tip. Please note that you should reduce this value by the tower radius to obtain the actual tower clearance.; N/A
ElastoDyn['TwrClrnc2']        = False     # (m); Blade 2 tip-to-tower clearance estimate. This is computed as the perpendicular distance from the yaw axis to the tip of blade 1 when the blade tip is below the yaw bearing. When the tip of blade 1 is above the yaw bearing, it is computed as the absolute distance from the yaw bearing to the blade tip. Please note that you should reduce this value by the tower radius to obtain the actual tower clearance.; N/A
ElastoDyn['Tip2Twr2']         = False     # (m); Blade 2 tip-to-tower clearance estimate. This is computed as the perpendicular distance from the yaw axis to the tip of blade 1 when the blade tip is below the yaw bearing. When the tip of blade 1 is above the yaw bearing, it is computed as the absolute distance from the yaw bearing to the blade tip. Please note that you should reduce this value by the tower radius to obtain the actual tower clearance.; N/A

# Blade 3 Tip Motions
ElastoDyn['TipDxc3']          = True      # (m); Blade 3 out-of-plane tip deflection (relative to the pitch axis); Directed along the xc3-axis
ElastoDyn['OoPDefl3']         = False     # (m); Blade 3 out-of-plane tip deflection (relative to the pitch axis); Directed along the xc3-axis
ElastoDyn['TipDyc3']          = True      # (m); Blade 3 in-plane tip deflection (relative to the pitch axis); Directed along the yc3-axis
ElastoDyn['IPDefl3']          = False     # (m); Blade 3 in-plane tip deflection (relative to the pitch axis); Directed along the yc3-axis
ElastoDyn['TipDzc3']          = True      # (m); Blade 3 axial tip deflection (relative to the pitch axis); Directed along the zc3- and zb3-axes
ElastoDyn['TipDzb3']          = True      # (m); Blade 3 axial tip deflection (relative to the pitch axis); Directed along the zc3- and zb3-axes
ElastoDyn['TipDxb3']          = True      # (m); Blade 3 flapwise tip deflection (relative to the pitch axis); Directed along the xb3-axis
ElastoDyn['TipDyb3']          = True      # (m); Blade 3 edgewise tip deflection (relative to the pitch axis); Directed along the yb3-axis
ElastoDyn['TipALxb3']         = False     # (m/s^2); Blade 3 local flapwise tip acceleration (absolute); Directed along the local xb3-axis
ElastoDyn['TipALyb3']         = False     # (m/s^2); Blade 3 local edgewise tip acceleration (absolute); Directed along the local yb3-axis
ElastoDyn['TipALzb3']         = False     # (m/s^2); Blade 3 local axial tip acceleration (absolute); Directed along the local zb3-axis
ElastoDyn['TipALgxb3']        = False     # (m/s^2); Blade 3 local flapwise tip acceleration (relative to g); Directed along the local xb3-axis
ElastoDyn['TipALgyb3']        = False     # (m/s^2); Blade 3 local edgewise tip acceleration (relative to g); Directed along the local yb3-axis
ElastoDyn['TipALgzb3']        = False     # (m/s^2); Blade 3 local axial tip acceleration (relative to g); Directed along the local zb3-axis
ElastoDyn['TipRDxb3']         = False     # (deg); Blade 3 roll (angular/rotational) tip deflection (relative to the undeflected position). In ADAMS, it is output as an Euler angle computed as the 3rd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the xb3-axis
ElastoDyn['RollDefl3']        = False     # (deg); Blade 3 roll (angular/rotational) tip deflection (relative to the undeflected position). In ADAMS, it is output as an Euler angle computed as the 3rd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the xb3-axis
ElastoDyn['TipRDyb3']         = False     # (deg); Blade 3 pitch (angular/rotational) tip deflection (relative to the undeflected position). In ADAMS, it is output as an Euler angle computed as the 2nd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the yb3-axis
ElastoDyn['PtchDefl3']        = False     # (deg); Blade 3 pitch (angular/rotational) tip deflection (relative to the undeflected position). In ADAMS, it is output as an Euler angle computed as the 2nd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the yb3-axis
ElastoDyn['TipRDzc3']         = False     # (deg); Blade 3 torsional tip deflection (relative to the undeflected position). This output will always be zero for FAST simulation results. Use it for examining blade torsional deflections of ADAMS simulations run using ADAMS datasets created using the FAST-to-ADAMS preprocessor. In ADAMS, it is output as an Euler angle computed as the 1st rotation in the yaw-pitch-roll rotation sequence.  Please note that this output uses the opposite of the sign convention used for blade pitch angles.; About the zc3- and zb3-axes
ElastoDyn['TipRDzb3']         = False     # (deg); Blade 3 torsional tip deflection (relative to the undeflected position). This output will always be zero for FAST simulation results. Use it for examining blade torsional deflections of ADAMS simulations run using ADAMS datasets created using the FAST-to-ADAMS preprocessor. In ADAMS, it is output as an Euler angle computed as the 1st rotation in the yaw-pitch-roll rotation sequence.  Please note that this output uses the opposite of the sign convention used for blade pitch angles.; About the zc3- and zb3-axes
ElastoDyn['TwstDefl3']        = False     # (deg); Blade 3 torsional tip deflection (relative to the undeflected position). This output will always be zero for FAST simulation results. Use it for examining blade torsional deflections of ADAMS simulations run using ADAMS datasets created using the FAST-to-ADAMS preprocessor. In ADAMS, it is output as an Euler angle computed as the 1st rotation in the yaw-pitch-roll rotation sequence.  Please note that this output uses the opposite of the sign convention used for blade pitch angles.; About the zc3- and zb3-axes
ElastoDyn['TipClrnc3']        = False     # (m); Blade 3 tip-to-tower clearance estimate. This is computed as the perpendicular distance from the yaw axis to the tip of blade 1 when the blade tip is below the yaw bearing. When the tip of blade 1 is above the yaw bearing, it is computed as the absolute distance from the yaw bearing to the blade tip. Please note that you should reduce this value by the tower radius to obtain the actual tower clearance.; N/A
ElastoDyn['TwrClrnc3']        = False     # (m); Blade 3 tip-to-tower clearance estimate. This is computed as the perpendicular distance from the yaw axis to the tip of blade 1 when the blade tip is below the yaw bearing. When the tip of blade 1 is above the yaw bearing, it is computed as the absolute distance from the yaw bearing to the blade tip. Please note that you should reduce this value by the tower radius to obtain the actual tower clearance.; N/A
ElastoDyn['Tip2Twr3']         = False     # (m); Blade 3 tip-to-tower clearance estimate. This is computed as the perpendicular distance from the yaw axis to the tip of blade 1 when the blade tip is below the yaw bearing. When the tip of blade 1 is above the yaw bearing, it is computed as the absolute distance from the yaw bearing to the blade tip. Please note that you should reduce this value by the tower radius to obtain the actual tower clearance.; N/A

# Blade 1 Local Span Motions
ElastoDyn['Spn1ALxb1']        = False     # (m/s^2); Blade 1 local flapwise acceleration (absolute) of span station 1; Directed along the local xb1-axis
ElastoDyn['Spn1ALyb1']        = False     # (m/s^2); Blade 1 local edgewise acceleration (absolute) of span station 1; Directed along the local yb1-axis
ElastoDyn['Spn1ALzb1']        = False     # (m/s^2); Blade 1 local axial acceleration (absolute) of span station 1; Directed along the local zb1-axis
ElastoDyn['Spn2ALxb1']        = False     # (m/s^2); Blade 1 local flapwise acceleration (absolute) of span  station 2; Directed along the local xb1-axis
ElastoDyn['Spn2ALyb1']        = False     # (m/s^2); Blade 1 local edgewise acceleration (absolute) of span station 2; Directed along the local yb1-axis
ElastoDyn['Spn2ALzb1']        = False     # (m/s^2); Blade 1 local axial acceleration (absolute) of span station 2; Directed along the local zb1-axis
ElastoDyn['Spn3ALxb1']        = False     # (m/s^2); Blade 1 local flapwise acceleration (absolute) of span station 3; Directed along the local xb1-axis
ElastoDyn['Spn3ALyb1']        = False     # (m/s^2); Blade 1 local edgewise acceleration (absolute) of span station 3; Directed along the local yb1-axis
ElastoDyn['Spn3ALzb1']        = False     # (m/s^2); Blade 1 local axial acceleration (absolute) of span station 3; Directed along the local zb1-axis
ElastoDyn['Spn4ALxb1']        = False     # (m/s^2); Blade 1 local flapwise acceleration (absolute) of span station 4; Directed along the local xb1-axis
ElastoDyn['Spn4ALyb1']        = False     # (m/s^2); Blade 1 local edgewise acceleration (absolute) of span station 4; Directed along the local yb1-axis
ElastoDyn['Spn4ALzb1']        = False     # (m/s^2); Blade 1 local axial acceleration (absolute) of span station 4; Directed along the local zb1-axis
ElastoDyn['Spn5ALxb1']        = False     # (m/s^2); Blade 1 local flapwise acceleration (absolute) of span station 5; Directed along the local xb1-axis
ElastoDyn['Spn5ALyb1']        = False     # (m/s^2); Blade 1 local edgewise acceleration (absolute) of span station 5; Directed along the local yb1-axis
ElastoDyn['Spn5ALzb1']        = False     # (m/s^2); Blade 1 local axial acceleration (absolute) of span station 5; Directed along the local zb1-axis
ElastoDyn['Spn6ALxb1']        = False     # (m/s^2); Blade 1 local flapwise acceleration (absolute) of span station 6; Directed along the local xb1-axis
ElastoDyn['Spn6ALyb1']        = False     # (m/s^2); Blade 1 local edgewise acceleration (absolute) of span station 6; Directed along the local yb1-axis
ElastoDyn['Spn6ALzb1']        = False     # (m/s^2); Blade 1 local axial acceleration (absolute) of span station 6; Directed along the local zb1-axis
ElastoDyn['Spn7ALxb1']        = False     # (m/s^2); Blade 1 local flapwise acceleration (absolute) of span station 7; Directed along the local xb1-axis
ElastoDyn['Spn7ALyb1']        = False     # (m/s^2); Blade 1 local edgewise acceleration (absolute) of span station 7; Directed along the local yb1-axis
ElastoDyn['Spn7ALzb1']        = False     # (m/s^2); Blade 1 local axial acceleration (absolute) of span station 7; Directed along the local zb1-axis
ElastoDyn['Spn8ALxb1']        = False     # (m/s^2); Blade 1 local flapwise acceleration (absolute) of span station 8; Directed along the local xb1-axis
ElastoDyn['Spn8ALyb1']        = False     # (m/s^2); Blade 1 local edgewise acceleration (absolute) of span station 8; Directed along the local yb1-axis
ElastoDyn['Spn8ALzb1']        = False     # (m/s^2); Blade 1 local axial acceleration (absolute) of span station 8; Directed along the local zb1-axis
ElastoDyn['Spn9ALxb1']        = False     # (m/s^2); Blade 1 local flapwise acceleration (absolute) of span station 9; Directed along the local xb1-axis
ElastoDyn['Spn9ALyb1']        = False     # (m/s^2); Blade 1 local edgewise acceleration (absolute) of span station 9; Directed along the local yb1-axis
ElastoDyn['Spn9ALzb1']        = False     # (m/s^2); Blade 1 local axial acceleration (absolute) of span station 9; Directed along the local zb1-axis
ElastoDyn['Spn1ALgxb1']       = False     # (m/s^2); Blade 1 local flapwise acceleration (relative to g) of span station 1; Directed along the local xb1-axis
ElastoDyn['Spn1ALgyb1']       = False     # (m/s^2); Blade 1 local edgewise acceleration (relative to g) of span station 1; Directed along the local yb1-axis
ElastoDyn['Spn1ALgzb1']       = False     # (m/s^2); Blade 1 local axial acceleration (relative to g) of span station 1; Directed along the local zb1-axis
ElastoDyn['Spn2ALgxb1']       = False     # (m/s^2); Blade 1 local flapwise acceleration (relative to g) of span  station 2; Directed along the local xb1-axis
ElastoDyn['Spn2ALgyb1']       = False     # (m/s^2); Blade 1 local edgewise acceleration (relative to g) of span station 2; Directed along the local yb1-axis
ElastoDyn['Spn2ALgzb1']       = False     # (m/s^2); Blade 1 local axial acceleration (relative to g) of span station 2; Directed along the local zb1-axis
ElastoDyn['Spn3ALgxb1']       = False     # (m/s^2); Blade 1 local flapwise acceleration (relative to g) of span station 3; Directed along the local xb1-axis
ElastoDyn['Spn3ALgyb1']       = False     # (m/s^2); Blade 1 local edgewise acceleration (relative to g) of span station 3; Directed along the local yb1-axis
ElastoDyn['Spn3ALgzb1']       = False     # (m/s^2); Blade 1 local axial acceleration (relative to g) of span station 3; Directed along the local zb1-axis
ElastoDyn['Spn4ALgxb1']       = False     # (m/s^2); Blade 1 local flapwise acceleration (relative to g) of span station 4; Directed along the local xb1-axis
ElastoDyn['Spn4ALgyb1']       = False     # (m/s^2); Blade 1 local edgewise acceleration (relative to g) of span station 4; Directed along the local yb1-axis
ElastoDyn['Spn4ALgzb1']       = False     # (m/s^2); Blade 1 local axial acceleration (relative to g) of span station 4; Directed along the local zb1-axis
ElastoDyn['Spn5ALgxb1']       = False     # (m/s^2); Blade 1 local flapwise acceleration (relative to g) of span station 5; Directed along the local xb1-axis
ElastoDyn['Spn5ALgyb1']       = False     # (m/s^2); Blade 1 local edgewise acceleration (relative to g) of span station 5; Directed along the local yb1-axis
ElastoDyn['Spn5ALgzb1']       = False     # (m/s^2); Blade 1 local axial acceleration (relative to g) of span station 5; Directed along the local zb1-axis
ElastoDyn['Spn6ALgxb1']       = False     # (m/s^2); Blade 1 local flapwise acceleration (relative to g) of span station 6; Directed along the local xb1-axis
ElastoDyn['Spn6ALgyb1']       = False     # (m/s^2); Blade 1 local edgewise acceleration (relative to g) of span station 6; Directed along the local yb1-axis
ElastoDyn['Spn6ALgzb1']       = False     # (m/s^2); Blade 1 local axial acceleration (relative to g) of span station 6; Directed along the local zb1-axis
ElastoDyn['Spn7ALgxb1']       = False     # (m/s^2); Blade 1 local flapwise acceleration (relative to g) of span station 7; Directed along the local xb1-axis
ElastoDyn['Spn7ALgyb1']       = False     # (m/s^2); Blade 1 local edgewise acceleration (relative to g) of span station 7; Directed along the local yb1-axis
ElastoDyn['Spn7ALgzb1']       = False     # (m/s^2); Blade 1 local axial acceleration (relative to g) of span station 7; Directed along the local zb1-axis
ElastoDyn['Spn8ALgxb1']       = False     # (m/s^2); Blade 1 local flapwise acceleration (relative to g) of span station 8; Directed along the local xb1-axis
ElastoDyn['Spn8ALgyb1']       = False     # (m/s^2); Blade 1 local edgewise acceleration (relative to g) of span station 8; Directed along the local yb1-axis
ElastoDyn['Spn8ALgzb1']       = False     # (m/s^2); Blade 1 local axial acceleration (relative to g) of span station 8; Directed along the local zb1-axis
ElastoDyn['Spn9ALgxb1']       = False     # (m/s^2); Blade 1 local flapwise acceleration (relative to g) of span station 9; Directed along the local xb1-axis
ElastoDyn['Spn9ALgyb1']       = False     # (m/s^2); Blade 1 local edgewise acceleration (relative to g) of span station 9; Directed along the local yb1-axis
ElastoDyn['Spn9ALgzb1']       = False     # (m/s^2); Blade 1 local axial acceleration (relative to g) of span station 9; Directed along the local zb1-axis
ElastoDyn['Spn1TDxb1']        = False     # (m); Blade 1 local flapwise (translational) deflection (relative to the undeflected position) of span station 1; Directed along the xb1-axis
ElastoDyn['Spn1TDyb1']        = False     # (m); Blade 1 local edgewise (translational) deflection (relative to the undeflected position) of span station 1; Directed along the yb1-axis
ElastoDyn['Spn1TDzb1']        = False     # (m); Blade 1 local axial (translational) deflection (relative to the undeflected position) of span station 1; Directed along the zb1-axis
ElastoDyn['Spn2TDxb1']        = False     # (m); Blade 1 local flapwise (translational) deflection (relative to the undeflected position) of span station 2; Directed along the xb1-axis
ElastoDyn['Spn2TDyb1']        = False     # (m); Blade 1 local edgewise (translational) deflection (relative to the undeflected position) of span station 2; Directed along the yb1-axis
ElastoDyn['Spn2TDzb1']        = False     # (m); Blade 1 local axial (translational) deflection (relative to the undeflected position) of span station 2; Directed along the zb1-axis
ElastoDyn['Spn3TDxb1']        = False     # (m); Blade 1 local flapwise (translational) deflection (relative to the undeflected position) of span station 3; Directed along the xb1-axis
ElastoDyn['Spn3TDyb1']        = False     # (m); Blade 1 local edgewise (translational) deflection (relative to the undeflected position) of span station 3; Directed along the yb1-axis
ElastoDyn['Spn3TDzb1']        = False     # (m); Blade 1 local axial (translational) deflection (relative to the undeflected position) of span station 3; Directed along the zb1-axis
ElastoDyn['Spn4TDxb1']        = False     # (m); Blade 1 local flapwise (translational) deflection (relative to the undeflected position) of span station 4; Directed along the xb1-axis
ElastoDyn['Spn4TDyb1']        = False     # (m); Blade 1 local edgewise (translational) deflection (relative to the undeflected position) of span station 4; Directed along the yb1-axis
ElastoDyn['Spn4TDzb1']        = False     # (m); Blade 1 local axial (translational) deflection (relative to the undeflected position) of span station 4; Directed along the zb1-axis
ElastoDyn['Spn5TDxb1']        = False     # (m); Blade 1 local flapwise (translational) deflection (relative to the undeflected position) of span station 5; Directed along the xb1-axis
ElastoDyn['Spn5TDyb1']        = False     # (m); Blade 1 local edgewise (translational) deflection (relative to the undeflected position) of span station 5; Directed along the yb1-axis
ElastoDyn['Spn5TDzb1']        = False     # (m); Blade 1 local axial (translational) deflection (relative to the undeflected position) of span station 5; Directed along the zb1-axis
ElastoDyn['Spn6TDxb1']        = False     # (m); Blade 1 local flapwise (translational) deflection (relative to the undeflected position) of span station 6; Directed along the xb1-axis
ElastoDyn['Spn6TDyb1']        = False     # (m); Blade 1 local edgewise (translational) deflection (relative to the undeflected position) of span station 6; Directed along the yb1-axis
ElastoDyn['Spn6TDzb1']        = False     # (m); Blade 1 local axial (translational) deflection (relative to the undeflected position) of span station 6; Directed along the zb1-axis
ElastoDyn['Spn7TDxb1']        = False     # (m); Blade 1 local flapwise (translational) deflection (relative to the undeflected position) of span station 7; Directed along the xb1-axis
ElastoDyn['Spn7TDyb1']        = False     # (m); Blade 1 local edgewise (translational) deflection (relative to the undeflected position) of span station 7; Directed along the yb1-axis
ElastoDyn['Spn7TDzb1']        = False     # (m); Blade 1 local axial (translational) deflection (relative to the undeflected position) of span station 7; Directed along the zb1-axis
ElastoDyn['Spn8TDxb1']        = False     # (m); Blade 1 local flapwise (translational) deflection (relative to the undeflected position) of span station 8; Directed along the xb1-axis
ElastoDyn['Spn8TDyb1']        = False     # (m); Blade 1 local edgewise (translational) deflection (relative to the undeflected position) of span station 8; Directed along the yb1-axis
ElastoDyn['Spn8TDzb1']        = False     # (m); Blade 1 local axial (translational) deflection (relative to the undeflected position) of span station 8; Directed along the zb1-axis
ElastoDyn['Spn9TDxb1']        = False     # (m); Blade 1 local flapwise (translational) deflection (relative to the undeflected position) of span station 9; Directed along the xb1-axis
ElastoDyn['Spn9TDyb1']        = False     # (m); Blade 1 local edgewise (translational) deflection (relative to the undeflected position) of span station 9; Directed along the yb1-axis
ElastoDyn['Spn9TDzb1']        = False     # (m); Blade 1 local axial (translational) deflection (relative to the undeflected position) of span station 9; Directed along the zb1-axis
ElastoDyn['Spn1RDxb1']        = False     # (deg); Blade 1 local roll (angular/rotational)  deflection (relative to the undeflected position) of span station 1. In ADAMS, it is output as an Euler angle computed as the 3rd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the local xb1-axis
ElastoDyn['Spn1RDyb1']        = False     # (deg); Blade 1 local pitch (angular/rotational) deflection (relative to the undeflected position) of span station 1. In ADAMS, it is output as an Euler angle computed as the 2nd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the local yb1-axis
ElastoDyn['Spn1RDzb1']        = False     # (deg); Blade 1 local torsional (angular/rotational) deflection (relative to the undeflected position) of span station 1. This output will always be zero for FAST simulation results. Use it for examining blade torsional deflections of ADAMS simulations run using ADAMS datasets created using the FAST-to-ADAMS preprocessor. In ADAMS, it is output as an Euler angle computed as the 1st rotation in the yaw-pitch-roll rotation sequence.  Please note that this output uses the opposite of the sign convention used for blade pitch angles.; About the local zb1-axis
ElastoDyn['Spn2RDxb1']        = False     # (deg); Blade 1 local roll (angular/rotational)  deflection (relative to the undeflected position) of span station 2. In ADAMS, it is output as an Euler angle computed as the 3rd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the local xb1-axis
ElastoDyn['Spn2RDyb1']        = False     # (deg); Blade 1 local pitch (angular/rotational) deflection (relative to the undeflected position) of span station 2. In ADAMS, it is output as an Euler angle computed as the 2nd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the local yb1-axis
ElastoDyn['Spn2RDzb1']        = False     # (deg); Blade 1 local torsional (angular/rotational) deflection (relative to the undeflected position) of span station 2. This output will always be zero for FAST simulation results. Use it for examining blade torsional deflections of ADAMS simulations run using ADAMS datasets created using the FAST-to-ADAMS preprocessor. In ADAMS, it is output as an Euler angle computed as the 1st rotation in the yaw-pitch-roll rotation sequence.  Please note that this output uses the opposite of the sign convention used for blade pitch angles.; About the local zb1-axis
ElastoDyn['Spn3RDxb1']        = False     # (deg); Blade 1 local roll (angular/rotational)  deflection (relative to the undeflected position) of span station 3. In ADAMS, it is output as an Euler angle computed as the 3rd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the local xb1-axis
ElastoDyn['Spn3RDyb1']        = False     # (deg); Blade 1 local pitch (angular/rotational) deflection (relative to the undeflected position) of span station 3. In ADAMS, it is output as an Euler angle computed as the 2nd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the local yb1-axis
ElastoDyn['Spn3RDzb1']        = False     # (deg); Blade 1 local torsional (angular/rotational) deflection (relative to the undeflected position) of span station 3. This output will always be zero for FAST simulation results. Use it for examining blade torsional deflections of ADAMS simulations run using ADAMS datasets created using the FAST-to-ADAMS preprocessor. In ADAMS, it is output as an Euler angle computed as the 1st rotation in the yaw-pitch-roll rotation sequence.  Please note that this output uses the opposite of the sign convention used for blade pitch angles.; About the local zb1-axis
ElastoDyn['Spn4RDxb1']        = False     # (deg); Blade 1 local roll (angular/rotational)  deflection (relative to the undeflected position) of span station 4. In ADAMS, it is output as an Euler angle computed as the 3rd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the local xb1-axis
ElastoDyn['Spn4RDyb1']        = False     # (deg); Blade 1 local pitch (angular/rotational) deflection (relative to the undeflected position) of span station 4. In ADAMS, it is output as an Euler angle computed as the 2nd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the local yb1-axis
ElastoDyn['Spn4RDzb1']        = False     # (deg); Blade 1 local torsional (angular/rotational) deflection (relative to the undeflected position) of span station 4. This output will always be zero for FAST simulation results. Use it for examining blade torsional deflections of ADAMS simulations run using ADAMS datasets created using the FAST-to-ADAMS preprocessor. In ADAMS, it is output as an Euler angle computed as the 1st rotation in the yaw-pitch-roll rotation sequence.  Please note that this output uses the opposite of the sign convention used for blade pitch angles.; About the local zb1-axis
ElastoDyn['Spn5RDxb1']        = False     # (deg); Blade 1 local roll (angular/rotational)  deflection (relative to the undeflected position) of span station 5. In ADAMS, it is output as an Euler angle computed as the 3rd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the local xb1-axis
ElastoDyn['Spn5RDyb1']        = False     # (deg); Blade 1 local pitch (angular/rotational) deflection (relative to the undeflected position) of span station 5. In ADAMS, it is output as an Euler angle computed as the 2nd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the local yb1-axis
ElastoDyn['Spn5RDzb1']        = False     # (deg); Blade 1 local torsional (angular/rotational) deflection (relative to the undeflected position) of span station 5. This output will always be zero for FAST simulation results. Use it for examining blade torsional deflections of ADAMS simulations run using ADAMS datasets created using the FAST-to-ADAMS preprocessor. In ADAMS, it is output as an Euler angle computed as the 1st rotation in the yaw-pitch-roll rotation sequence.  Please note that this output uses the opposite of the sign convention used for blade pitch angles.; About the local zb1-axis
ElastoDyn['Spn6RDxb1']        = False     # (deg); Blade 1 local roll (angular/rotational)  deflection (relative to the undeflected position) of span station 6. In ADAMS, it is output as an Euler angle computed as the 3rd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the local xb1-axis
ElastoDyn['Spn6RDyb1']        = False     # (deg); Blade 1 local pitch (angular/rotational) deflection (relative to the undeflected position) of span station 6. In ADAMS, it is output as an Euler angle computed as the 2nd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the local yb1-axis
ElastoDyn['Spn6RDzb1']        = False     # (deg); Blade 1 local torsional (angular/rotational) deflection (relative to the undeflected position) of span station 6. This output will always be zero for FAST simulation results. Use it for examining blade torsional deflections of ADAMS simulations run using ADAMS datasets created using the FAST-to-ADAMS preprocessor. In ADAMS, it is output as an Euler angle computed as the 1st rotation in the yaw-pitch-roll rotation sequence.  Please note that this output uses the opposite of the sign convention used for blade pitch angles.; About the local zb1-axis
ElastoDyn['Spn7RDxb1']        = False     # (deg); Blade 1 local roll (angular/rotational)  deflection (relative to the undeflected position) of span station 7. In ADAMS, it is output as an Euler angle computed as the 3rd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the local xb1-axis
ElastoDyn['Spn7RDyb1']        = False     # (deg); Blade 1 local pitch (angular/rotational) deflection (relative to the undeflected position) of span station 7. In ADAMS, it is output as an Euler angle computed as the 2nd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the local yb1-axis
ElastoDyn['Spn7RDzb1']        = False     # (deg); Blade 1 local torsional (angular/rotational) deflection (relative to the undeflected position) of span station 7. This output will always be zero for FAST simulation results. Use it for examining blade torsional deflections of ADAMS simulations run using ADAMS datasets created using the FAST-to-ADAMS preprocessor. In ADAMS, it is output as an Euler angle computed as the 1st rotation in the yaw-pitch-roll rotation sequence.  Please note that this output uses the opposite of the sign convention used for blade pitch angles.; About the local zb1-axis
ElastoDyn['Spn8RDxb1']        = False     # (deg); Blade 1 local roll (angular/rotational)  deflection (relative to the undeflected position) of span station 8. In ADAMS, it is output as an Euler angle computed as the 3rd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the local xb1-axis
ElastoDyn['Spn8RDyb1']        = False     # (deg); Blade 1 local pitch (angular/rotational) deflection (relative to the undeflected position) of span station 8. In ADAMS, it is output as an Euler angle computed as the 2nd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the local yb1-axis
ElastoDyn['Spn8RDzb1']        = False     # (deg); Blade 1 local torsional (angular/rotational) deflection (relative to the undeflected position) of span station 8. This output will always be zero for FAST simulation results. Use it for examining blade torsional deflections of ADAMS simulations run using ADAMS datasets created using the FAST-to-ADAMS preprocessor. In ADAMS, it is output as an Euler angle computed as the 1st rotation in the yaw-pitch-roll rotation sequence.  Please note that this output uses the opposite of the sign convention used for blade pitch angles.; About the local zb1-axis
ElastoDyn['Spn9RDxb1']        = False     # (deg); Blade 1 local roll (angular/rotational)  deflection (relative to the undeflected position) of span station 9. In ADAMS, it is output as an Euler angle computed as the 3rd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the local xb1-axis
ElastoDyn['Spn9RDyb1']        = False     # (deg); Blade 1 local pitch (angular/rotational) deflection (relative to the undeflected position) of span station 9. In ADAMS, it is output as an Euler angle computed as the 2nd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the local yb1-axis
ElastoDyn['Spn9RDzb1']        = False     # (deg); Blade 1 local torsional (angular/rotational) deflection (relative to the undeflected position) of span station 9. This output will always be zero for FAST simulation results. Use it for examining blade torsional deflections of ADAMS simulations run using ADAMS datasets created using the FAST-to-ADAMS preprocessor. In ADAMS, it is output as an Euler angle computed as the 1st rotation in the yaw-pitch-roll rotation sequence.  Please note that this output uses the opposite of the sign convention used for blade pitch angles.; About the local zb1-axis

# Blade 2 Local Span Motions
ElastoDyn['Spn1ALxb2']        = False     # (m/s^2); Blade 2 local flapwise acceleration (absolute) of span station 1; Directed along the local xb2-axis
ElastoDyn['Spn1ALyb2']        = False     # (m/s^2); Blade 2 local edgewise acceleration (absolute) of span station 1; Directed along the local yb2-axis
ElastoDyn['Spn1ALzb2']        = False     # (m/s^2); Blade 2 local axial acceleration (absolute) of span station 1; Directed along the local zb2-axis
ElastoDyn['Spn2ALxb2']        = False     # (m/s^2); Blade 2 local flapwise acceleration (absolute) of span station 2; Directed along the local xb2-axis
ElastoDyn['Spn2ALyb2']        = False     # (m/s^2); Blade 2 local edgewise acceleration (absolute) of span station 2; Directed along the local yb2-axis
ElastoDyn['Spn2ALzb2']        = False     # (m/s^2); Blade 2 local axial acceleration (absolute) of span station 2; Directed along the local zb2-axis
ElastoDyn['Spn3ALxb2']        = False     # (m/s^2); Blade 2 local flapwise acceleration (absolute) of span station 3; Directed along the local xb2-axis
ElastoDyn['Spn3ALyb2']        = False     # (m/s^2); Blade 2 local edgewise acceleration (absolute) of span station 3; Directed along the local yb2-axis
ElastoDyn['Spn3ALzb2']        = False     # (m/s^2); Blade 2 local axial acceleration (absolute) of span station 3; Directed along the local zb2-axis
ElastoDyn['Spn4ALxb2']        = False     # (m/s^2); Blade 2 local flapwise acceleration (absolute) of span station 4; Directed along the local xb2-axis
ElastoDyn['Spn4ALyb2']        = False     # (m/s^2); Blade 2 local edgewise acceleration (absolute) of span station 4; Directed along the local yb2-axis
ElastoDyn['Spn4ALzb2']        = False     # (m/s^2); Blade 2 local axial acceleration (absolute) of span station 4; Directed along the local zb2-axis
ElastoDyn['Spn5ALxb2']        = False     # (m/s^2); Blade 2 local flapwise acceleration (absolute) of span station 5; Directed along the local xb2-axis
ElastoDyn['Spn5ALyb2']        = False     # (m/s^2); Blade 2 local edgewise acceleration (absolute) of span station 5; Directed along the local yb2-axis
ElastoDyn['Spn5ALzb2']        = False     # (m/s^2); Blade 2 local axial acceleration (absolute) of span station 5; Directed along the local zb2-axis
ElastoDyn['Spn6ALxb2']        = False     # (m/s^2); Blade 2 local flapwise acceleration (absolute) of span station 6; Directed along the local xb2-axis
ElastoDyn['Spn6ALyb2']        = False     # (m/s^2); Blade 2 local edgewise acceleration (absolute) of span station 6; Directed along the local yb2-axis
ElastoDyn['Spn6ALzb2']        = False     # (m/s^2); Blade 2 local axial acceleration (absolute) of span station 6; Directed along the local zb2-axis
ElastoDyn['Spn7ALxb2']        = False     # (m/s^2); Blade 2 local flapwise acceleration (absolute) of span station 7; Directed along the local xb2-axis
ElastoDyn['Spn7ALyb2']        = False     # (m/s^2); Blade 2 local edgewise acceleration (absolute) of span station 7; Directed along the local yb2-axis
ElastoDyn['Spn7ALzb2']        = False     # (m/s^2); Blade 2 local axial acceleration (absolute) of span station 7; Directed along the local zb2-axis
ElastoDyn['Spn8ALxb2']        = False     # (m/s^2); Blade 2 local flapwise acceleration (absolute) of span station 8; Directed along the local xb2-axis
ElastoDyn['Spn8ALyb2']        = False     # (m/s^2); Blade 2 local edgewise acceleration (absolute) of span station 8; Directed along the local yb2-axis
ElastoDyn['Spn8ALzb2']        = False     # (m/s^2); Blade 2 local axial acceleration (absolute) of span station 8; Directed along the local zb2-axis
ElastoDyn['Spn9ALxb2']        = False     # (m/s^2); Blade 2 local flapwise acceleration (absolute) of span station 9; Directed along the local xb2-axis
ElastoDyn['Spn9ALyb2']        = False     # (m/s^2); Blade 2 local edgewise acceleration (absolute) of span station 9; Directed along the local yb2-axis
ElastoDyn['Spn9ALzb2']        = False     # (m/s^2); Blade 2 local axial acceleration (absolute) of span station 9; Directed along the local zb2-axis
ElastoDyn['Spn1ALgxb2']       = False     # (m/s^2); Blade 2 local flapwise acceleration (relative to g) of span station 1; Directed along the local xb2-axis
ElastoDyn['Spn1ALgyb2']       = False     # (m/s^2); Blade 2 local edgewise acceleration (relative to g) of span station 1; Directed along the local yb2-axis
ElastoDyn['Spn1ALgzb2']       = False     # (m/s^2); Blade 2 local axial acceleration (relative to g) of span station 1; Directed along the local zb2-axis
ElastoDyn['Spn2ALgxb2']       = False     # (m/s^2); Blade 2 local flapwise acceleration (relative to g) of span station 2; Directed along the local xb2-axis
ElastoDyn['Spn2ALgyb2']       = False     # (m/s^2); Blade 2 local edgewise acceleration (relative to g) of span station 2; Directed along the local yb2-axis
ElastoDyn['Spn2ALgzb2']       = False     # (m/s^2); Blade 2 local axial acceleration (relative to g) of span station 2; Directed along the local zb2-axis
ElastoDyn['Spn3ALgxb2']       = False     # (m/s^2); Blade 2 local flapwise acceleration (relative to g) of span station 3; Directed along the local xb2-axis
ElastoDyn['Spn3ALgyb2']       = False     # (m/s^2); Blade 2 local edgewise acceleration (relative to g) of span station 3; Directed along the local yb2-axis
ElastoDyn['Spn3ALgzb2']       = False     # (m/s^2); Blade 2 local axial acceleration (relative to g) of span station 3; Directed along the local zb2-axis
ElastoDyn['Spn4ALgxb2']       = False     # (m/s^2); Blade 2 local flapwise acceleration (relative to g) of span station 4; Directed along the local xb2-axis
ElastoDyn['Spn4ALgyb2']       = False     # (m/s^2); Blade 2 local edgewise acceleration (relative to g) of span station 4; Directed along the local yb2-axis
ElastoDyn['Spn4ALgzb2']       = False     # (m/s^2); Blade 2 local axial acceleration (relative to g) of span station 4; Directed along the local zb2-axis
ElastoDyn['Spn5ALgxb2']       = False     # (m/s^2); Blade 2 local flapwise acceleration (relative to g) of span station 5; Directed along the local xb2-axis
ElastoDyn['Spn5ALgyb2']       = False     # (m/s^2); Blade 2 local edgewise acceleration (relative to g) of span station 5; Directed along the local yb2-axis
ElastoDyn['Spn5ALgzb2']       = False     # (m/s^2); Blade 2 local axial acceleration (relative to g) of span station 5; Directed along the local zb2-axis
ElastoDyn['Spn6ALgxb2']       = False     # (m/s^2); Blade 2 local flapwise acceleration (relative to g) of span station 6; Directed along the local xb2-axis
ElastoDyn['Spn6ALgyb2']       = False     # (m/s^2); Blade 2 local edgewise acceleration (relative to g) of span station 6; Directed along the local yb2-axis
ElastoDyn['Spn6ALgzb2']       = False     # (m/s^2); Blade 2 local axial acceleration (relative to g) of span station 6; Directed along the local zb2-axis
ElastoDyn['Spn7ALgxb2']       = False     # (m/s^2); Blade 2 local flapwise acceleration (relative to g) of span station 7; Directed along the local xb2-axis
ElastoDyn['Spn7ALgyb2']       = False     # (m/s^2); Blade 2 local edgewise acceleration (relative to g) of span station 7; Directed along the local yb2-axis
ElastoDyn['Spn7ALgzb2']       = False     # (m/s^2); Blade 2 local axial acceleration (relative to g) of span station 7; Directed along the local zb2-axis
ElastoDyn['Spn8ALgxb2']       = False     # (m/s^2); Blade 2 local flapwise acceleration (relative to g) of span station 8; Directed along the local xb2-axis
ElastoDyn['Spn8ALgyb2']       = False     # (m/s^2); Blade 2 local edgewise acceleration (relative to g) of span station 8; Directed along the local yb2-axis
ElastoDyn['Spn8ALgzb2']       = False     # (m/s^2); Blade 2 local axial acceleration (relative to g) of span station 8; Directed along the local zb2-axis
ElastoDyn['Spn9ALgxb2']       = False     # (m/s^2); Blade 2 local flapwise acceleration (relative to g) of span station 9; Directed along the local xb2-axis
ElastoDyn['Spn9ALgyb2']       = False     # (m/s^2); Blade 2 local edgewise acceleration (relative to g) of span station 9; Directed along the local yb2-axis
ElastoDyn['Spn9ALgzb2']       = False     # (m/s^2); Blade 2 local axial acceleration (relative to g) of span station 9; Directed along the local zb2-axis
ElastoDyn['Spn1TDxb2']        = False     # (m); Blade 2 local flapwise (translational) deflection (relative to the undeflected position) of span station 1; Directed along the xb2-axis
ElastoDyn['Spn1TDyb2']        = False     # (m); Blade 2 local edgewise (translational) deflection (relative to the undeflected position) of span station 1; Directed along the yb2-axis
ElastoDyn['Spn1TDzb2']        = False     # (m); Blade 2 local axial (translational) deflection (relative to the undeflected position) of span station 1; Directed along the zb2-axis
ElastoDyn['Spn2TDxb2']        = False     # (m); Blade 2 local flapwise (translational) deflection (relative to the undeflected position) of span station 2; Directed along the xb2-axis
ElastoDyn['Spn2TDyb2']        = False     # (m); Blade 2 local edgewise (translational) deflection (relative to the undeflected position) of span station 2; Directed along the yb2-axis
ElastoDyn['Spn2TDzb2']        = False     # (m); Blade 2 local axial (translational) deflection (relative to the undeflected position) of span station 2; Directed along the zb2-axis
ElastoDyn['Spn3TDxb2']        = False     # (m); Blade 2 local flapwise (translational) deflection (relative to the undeflected position) of span station 3; Directed along the xb2-axis
ElastoDyn['Spn3TDyb2']        = False     # (m); Blade 2 local edgewise (translational) deflection (relative to the undeflected position) of span station 3; Directed along the yb2-axis
ElastoDyn['Spn3TDzb2']        = False     # (m); Blade 2 local axial (translational) deflection (relative to the undeflected position) of span station 3; Directed along the zb2-axis
ElastoDyn['Spn4TDxb2']        = False     # (m); Blade 2 local flapwise (translational) deflection (relative to the undeflected position) of span station 4; Directed along the xb2-axis
ElastoDyn['Spn4TDyb2']        = False     # (m); Blade 2 local edgewise (translational) deflection (relative to the undeflected position) of span station 4; Directed along the yb2-axis
ElastoDyn['Spn4TDzb2']        = False     # (m); Blade 2 local axial (translational) deflection (relative to the undeflected position) of span station 4; Directed along the zb2-axis
ElastoDyn['Spn5TDxb2']        = False     # (m); Blade 2 local flapwise (translational) deflection (relative to the undeflected position) of span station 5; Directed along the xb2-axis
ElastoDyn['Spn5TDyb2']        = False     # (m); Blade 2 local edgewise (translational) deflection (relative to the undeflected position) of span station 5; Directed along the yb2-axis
ElastoDyn['Spn5TDzb2']        = False     # (m); Blade 2 local axial (translational) deflection (relative to the undeflected position) of span station 5; Directed along the zb2-axis
ElastoDyn['Spn6TDxb2']        = False     # (m); Blade 2 local flapwise (translational) deflection (relative to the undeflected position) of span station 6; Directed along the xb2-axis
ElastoDyn['Spn6TDyb2']        = False     # (m); Blade 2 local edgewise (translational) deflection (relative to the undeflected position) of span station 6; Directed along the yb2-axis
ElastoDyn['Spn6TDzb2']        = False     # (m); Blade 2 local axial (translational) deflection (relative to the undeflected position) of span station 6; Directed along the zb2-axis
ElastoDyn['Spn7TDxb2']        = False     # (m); Blade 2 local flapwise (translational) deflection (relative to the undeflected position) of span station 7; Directed along the xb2-axis
ElastoDyn['Spn7TDyb2']        = False     # (m); Blade 2 local edgewise (translational) deflection (relative to the undeflected position) of span station 7; Directed along the yb2-axis
ElastoDyn['Spn7TDzb2']        = False     # (m); Blade 2 local axial (translational) deflection (relative to the undeflected position) of span station 7; Directed along the zb2-axis
ElastoDyn['Spn8TDxb2']        = False     # (m); Blade 2 local flapwise (translational) deflection (relative to the undeflected position) of span station 8; Directed along the xb2-axis
ElastoDyn['Spn8TDyb2']        = False     # (m); Blade 2 local edgewise (translational) deflection (relative to the undeflected position) of span station 8; Directed along the yb2-axis
ElastoDyn['Spn8TDzb2']        = False     # (m); Blade 2 local axial (translational) deflection (relative to the undeflected position) of span station 8; Directed along the zb2-axis
ElastoDyn['Spn9TDxb2']        = False     # (m); Blade 2 local flapwise (translational) deflection (relative to the undeflected position) of span station 9; Directed along the xb2-axis
ElastoDyn['Spn9TDyb2']        = False     # (m); Blade 2 local edgewise (translational) deflection (relative to the undeflected position) of span station 9; Directed along the yb2-axis
ElastoDyn['Spn9TDzb2']        = False     # (m); Blade 2 local axial (translational) deflection (relative to the undeflected position) of span station 9; Directed along the zb2-axis
ElastoDyn['Spn1RDxb2']        = False     # (deg); Blade 2 local roll (angular/rotational)  deflection (relative to the undeflected position) of span station 1. In ADAMS, it is output as an Euler angle computed as the 3rd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the local xb2-axis
ElastoDyn['Spn1RDyb2']        = False     # (deg); Blade 2 local pitch (angular/rotational) deflection (relative to the undeflected position) of span station 1. In ADAMS, it is output as an Euler angle computed as the 2nd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the local yb2-axis
ElastoDyn['Spn1RDzb2']        = False     # (deg); Blade 2 local torsional (angular/rotational) deflection (relative to the undeflected position) of span station 1. This output will always be zero for FAST simulation results. Use it for examining blade torsional deflections of ADAMS simulations run using ADAMS datasets created using the FAST-to-ADAMS preprocessor. In ADAMS, it is output as an Euler angle computed as the 1st rotation in the yaw-pitch-roll rotation sequence.  Please note that this output uses the opposite of the sign convention used for blade pitch angles.; About the local zb2-axis
ElastoDyn['Spn2RDxb2']        = False     # (deg); Blade 2 local roll (angular/rotational)  deflection (relative to the undeflected position) of span station 2. In ADAMS, it is output as an Euler angle computed as the 3rd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the local xb2-axis
ElastoDyn['Spn2RDyb2']        = False     # (deg); Blade 2 local pitch (angular/rotational) deflection (relative to the undeflected position) of span station 2. In ADAMS, it is output as an Euler angle computed as the 2nd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the local yb2-axis
ElastoDyn['Spn2RDzb2']        = False     # (deg); Blade 2 local torsional (angular/rotational) deflection (relative to the undeflected position) of span station 2. This output will always be zero for FAST simulation results. Use it for examining blade torsional deflections of ADAMS simulations run using ADAMS datasets created using the FAST-to-ADAMS preprocessor. In ADAMS, it is output as an Euler angle computed as the 1st rotation in the yaw-pitch-roll rotation sequence.  Please note that this output uses the opposite of the sign convention used for blade pitch angles.; About the local zb2-axis
ElastoDyn['Spn3RDxb2']        = False     # (deg); Blade 2 local roll (angular/rotational)  deflection (relative to the undeflected position) of span station 3. In ADAMS, it is output as an Euler angle computed as the 3rd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the local xb2-axis
ElastoDyn['Spn3RDyb2']        = False     # (deg); Blade 2 local pitch (angular/rotational) deflection (relative to the undeflected position) of span station 3. In ADAMS, it is output as an Euler angle computed as the 2nd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the local yb2-axis
ElastoDyn['Spn3RDzb2']        = False     # (deg); Blade 2 local torsional (angular/rotational) deflection (relative to the undeflected position) of span station 3. This output will always be zero for FAST simulation results. Use it for examining blade torsional deflections of ADAMS simulations run using ADAMS datasets created using the FAST-to-ADAMS preprocessor. In ADAMS, it is output as an Euler angle computed as the 1st rotation in the yaw-pitch-roll rotation sequence.  Please note that this output uses the opposite of the sign convention used for blade pitch angles.; About the local zb2-axis
ElastoDyn['Spn4RDxb2']        = False     # (deg); Blade 2 local roll (angular/rotational)  deflection (relative to the undeflected position) of span station 4. In ADAMS, it is output as an Euler angle computed as the 3rd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the local xb2-axis
ElastoDyn['Spn4RDyb2']        = False     # (deg); Blade 2 local pitch (angular/rotational) deflection (relative to the undeflected position) of span station 4. In ADAMS, it is output as an Euler angle computed as the 2nd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the local yb2-axis
ElastoDyn['Spn4RDzb2']        = False     # (deg); Blade 2 local torsional (angular/rotational) deflection (relative to the undeflected position) of span station 4. This output will always be zero for FAST simulation results. Use it for examining blade torsional deflections of ADAMS simulations run using ADAMS datasets created using the FAST-to-ADAMS preprocessor. In ADAMS, it is output as an Euler angle computed as the 1st rotation in the yaw-pitch-roll rotation sequence.  Please note that this output uses the opposite of the sign convention used for blade pitch angles.; About the local zb2-axis
ElastoDyn['Spn5RDxb2']        = False     # (deg); Blade 2 local roll (angular/rotational)  deflection (relative to the undeflected position) of span station 5. In ADAMS, it is output as an Euler angle computed as the 3rd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the local xb2-axis
ElastoDyn['Spn5RDyb2']        = False     # (deg); Blade 2 local pitch (angular/rotational) deflection (relative to the undeflected position) of span station 5. In ADAMS, it is output as an Euler angle computed as the 2nd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the local yb2-axis
ElastoDyn['Spn5RDzb2']        = False     # (deg); Blade 2 local torsional (angular/rotational) deflection (relative to the undeflected position) of span station 5. This output will always be zero for FAST simulation results. Use it for examining blade torsional deflections of ADAMS simulations run using ADAMS datasets created using the FAST-to-ADAMS preprocessor. In ADAMS, it is output as an Euler angle computed as the 1st rotation in the yaw-pitch-roll rotation sequence.  Please note that this output uses the opposite of the sign convention used for blade pitch angles.; About the local zb2-axis
ElastoDyn['Spn6RDxb2']        = False     # (deg); Blade 2 local roll (angular/rotational)  deflection (relative to the undeflected position) of span station 6. In ADAMS, it is output as an Euler angle computed as the 3rd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the local xb2-axis
ElastoDyn['Spn6RDyb2']        = False     # (deg); Blade 2 local pitch (angular/rotational) deflection (relative to the undeflected position) of span station 6. In ADAMS, it is output as an Euler angle computed as the 2nd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the local yb2-axis
ElastoDyn['Spn6RDzb2']        = False     # (deg); Blade 2 local torsional (angular/rotational) deflection (relative to the undeflected position) of span station 6. This output will always be zero for FAST simulation results. Use it for examining blade torsional deflections of ADAMS simulations run using ADAMS datasets created using the FAST-to-ADAMS preprocessor. In ADAMS, it is output as an Euler angle computed as the 1st rotation in the yaw-pitch-roll rotation sequence.  Please note that this output uses the opposite of the sign convention used for blade pitch angles.; About the local zb2-axis
ElastoDyn['Spn7RDxb2']        = False     # (deg); Blade 2 local roll (angular/rotational)  deflection (relative to the undeflected position) of span station 7. In ADAMS, it is output as an Euler angle computed as the 3rd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the local xb2-axis
ElastoDyn['Spn7RDyb2']        = False     # (deg); Blade 2 local pitch (angular/rotational) deflection (relative to the undeflected position) of span station 7. In ADAMS, it is output as an Euler angle computed as the 2nd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the local yb2-axis
ElastoDyn['Spn7RDzb2']        = False     # (deg); Blade 2 local torsional (angular/rotational) deflection (relative to the undeflected position) of span station 7. This output will always be zero for FAST simulation results. Use it for examining blade torsional deflections of ADAMS simulations run using ADAMS datasets created using the FAST-to-ADAMS preprocessor. In ADAMS, it is output as an Euler angle computed as the 1st rotation in the yaw-pitch-roll rotation sequence.  Please note that this output uses the opposite of the sign convention used for blade pitch angles.; About the local zb2-axis
ElastoDyn['Spn8RDxb2']        = False     # (deg); Blade 2 local roll (angular/rotational)  deflection (relative to the undeflected position) of span station 8. In ADAMS, it is output as an Euler angle computed as the 3rd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the local xb2-axis
ElastoDyn['Spn8RDyb2']        = False     # (deg); Blade 2 local pitch (angular/rotational) deflection (relative to the undeflected position) of span station 8. In ADAMS, it is output as an Euler angle computed as the 2nd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the local yb2-axis
ElastoDyn['Spn8RDzb2']        = False     # (deg); Blade 2 local torsional (angular/rotational) deflection (relative to the undeflected position) of span station 8. This output will always be zero for FAST simulation results. Use it for examining blade torsional deflections of ADAMS simulations run using ADAMS datasets created using the FAST-to-ADAMS preprocessor. In ADAMS, it is output as an Euler angle computed as the 1st rotation in the yaw-pitch-roll rotation sequence.  Please note that this output uses the opposite of the sign convention used for blade pitch angles.; About the local zb2-axis
ElastoDyn['Spn9RDxb2']        = False     # (deg); Blade 2 local roll (angular/rotational)  deflection (relative to the undeflected position) of span station 9. In ADAMS, it is output as an Euler angle computed as the 3rd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the local xb2-axis
ElastoDyn['Spn9RDyb2']        = False     # (deg); Blade 2 local pitch (angular/rotational) deflection (relative to the undeflected position) of span station 9. In ADAMS, it is output as an Euler angle computed as the 2nd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the local yb2-axis
ElastoDyn['Spn9RDzb2']        = False     # (deg); Blade 2 local torsional (angular/rotational) deflection (relative to the undeflected position) of span station 9. This output will always be zero for FAST simulation results. Use it for examining blade torsional deflections of ADAMS simulations run using ADAMS datasets created using the FAST-to-ADAMS preprocessor. In ADAMS, it is output as an Euler angle computed as the 1st rotation in the yaw-pitch-roll rotation sequence.  Please note that this output uses the opposite of the sign convention used for blade pitch angles.; About the local zb2-axis

# Blade 3 Local Span Motions
ElastoDyn['Spn1ALxb3']        = False     # (m/s^2); Blade 3 local flapwise acceleration (absolute) of span station 1; Directed along the local xb3-axis
ElastoDyn['Spn1ALyb3']        = False     # (m/s^2); Blade 3 local edgewise acceleration (absolute) of span station 1; Directed along the local yb3-axis
ElastoDyn['Spn1ALzb3']        = False     # (m/s^2); Blade 3 local axial acceleration (absolute) of span station 1; Directed along the local zb3-axis
ElastoDyn['Spn2ALxb3']        = False     # (m/s^2); Blade 3 local flapwise acceleration (absolute) of span station 2; Directed along the local xb3-axis
ElastoDyn['Spn2ALyb3']        = False     # (m/s^2); Blade 3 local edgewise acceleration (absolute) of span station 2; Directed along the local yb3-axis
ElastoDyn['Spn2ALzb3']        = False     # (m/s^2); Blade 3 local axial acceleration (absolute) of span station 2; Directed along the local zb3-axis
ElastoDyn['Spn3ALxb3']        = False     # (m/s^2); Blade 3 local flapwise acceleration (absolute) of span station 3; Directed along the local xb3-axis
ElastoDyn['Spn3ALyb3']        = False     # (m/s^2); Blade 3 local edgewise acceleration (absolute) of span station 3; Directed along the local yb3-axis
ElastoDyn['Spn3ALzb3']        = False     # (m/s^2); Blade 3 local axial acceleration (absolute) of span station 3; Directed along the local zb3-axis
ElastoDyn['Spn4ALxb3']        = False     # (m/s^2); Blade 3 local flapwise acceleration (absolute) of span station 4; Directed along the local xb3-axis
ElastoDyn['Spn4ALyb3']        = False     # (m/s^2); Blade 3 local edgewise acceleration (absolute) of span station 4; Directed along the local yb3-axis
ElastoDyn['Spn4ALzb3']        = False     # (m/s^2); Blade 3 local axial acceleration (absolute) of span station 4; Directed along the local zb3-axis
ElastoDyn['Spn5ALxb3']        = False     # (m/s^2); Blade 3 local flapwise acceleration (absolute) of span station 5; Directed along the local xb3-axis
ElastoDyn['Spn5ALyb3']        = False     # (m/s^2); Blade 3 local edgewise acceleration (absolute) of span station 5; Directed along the local yb3-axis
ElastoDyn['Spn5ALzb3']        = False     # (m/s^2); Blade 3 local axial acceleration (absolute) of span station 5; Directed along the local zb3-axis
ElastoDyn['Spn6ALxb3']        = False     # (m/s^2); Blade 3 local flapwise acceleration (absolute) of span station 6; Directed along the local xb3-axis
ElastoDyn['Spn6ALyb3']        = False     # (m/s^2); Blade 3 local edgewise acceleration (absolute) of span station 6; Directed along the local yb3-axis
ElastoDyn['Spn6ALzb3']        = False     # (m/s^2); Blade 3 local axial acceleration (absolute) of span station 6; Directed along the local zb3-axis
ElastoDyn['Spn7ALxb3']        = False     # (m/s^2); Blade 3 local flapwise acceleration (absolute) of span station 7; Directed along the local xb3-axis
ElastoDyn['Spn7ALyb3']        = False     # (m/s^2); Blade 3 local edgewise acceleration (absolute) of span station 7; Directed along the local yb3-axis
ElastoDyn['Spn7ALzb3']        = False     # (m/s^2); Blade 3 local axial acceleration (absolute) of span station 7; Directed along the local zb3-axis
ElastoDyn['Spn8ALxb3']        = False     # (m/s^2); Blade 3 local flapwise acceleration (absolute) of span station 8; Directed along the local xb3-axis
ElastoDyn['Spn8ALyb3']        = False     # (m/s^2); Blade 3 local edgewise acceleration (absolute) of span station 8; Directed along the local yb3-axis
ElastoDyn['Spn8ALzb3']        = False     # (m/s^2); Blade 3 local axial acceleration (absolute) of span station 8; Directed along the local zb3-axis
ElastoDyn['Spn9ALxb3']        = False     # (m/s^2); Blade 3 local flapwise acceleration (absolute) of span station 9; Directed along the local xb3-axis
ElastoDyn['Spn9ALyb3']        = False     # (m/s^2); Blade 3 local edgewise acceleration (absolute) of span station 9; Directed along the local yb3-axis
ElastoDyn['Spn9ALzb3']        = False     # (m/s^2); Blade 3 local axial acceleration (absolute) of span station 9; Directed along the local zb3-axis
ElastoDyn['Spn1ALgxb3']       = False     # (m/s^2); Blade 3 local flapwise acceleration (relative to g) of span station 1; Directed along the local xb3-axis
ElastoDyn['Spn1ALgyb3']       = False     # (m/s^2); Blade 3 local edgewise acceleration (relative to g) of span station 1; Directed along the local yb3-axis
ElastoDyn['Spn1ALgzb3']       = False     # (m/s^2); Blade 3 local axial acceleration (relative to g) of span station 1; Directed along the local zb3-axis
ElastoDyn['Spn2ALgxb3']       = False     # (m/s^2); Blade 3 local flapwise acceleration (relative to g) of span station 2; Directed along the local xb3-axis
ElastoDyn['Spn2ALgyb3']       = False     # (m/s^2); Blade 3 local edgewise acceleration (relative to g) of span station 2; Directed along the local yb3-axis
ElastoDyn['Spn2ALgzb3']       = False     # (m/s^2); Blade 3 local axial acceleration (relative to g) of span station 2; Directed along the local zb3-axis
ElastoDyn['Spn3ALgxb3']       = False     # (m/s^2); Blade 3 local flapwise acceleration (relative to g) of span station 3; Directed along the local xb3-axis
ElastoDyn['Spn3ALgyb3']       = False     # (m/s^2); Blade 3 local edgewise acceleration (relative to g) of span station 3; Directed along the local yb3-axis
ElastoDyn['Spn3ALgzb3']       = False     # (m/s^2); Blade 3 local axial acceleration (relative to g) of span station 3; Directed along the local zb3-axis
ElastoDyn['Spn4ALgxb3']       = False     # (m/s^2); Blade 3 local flapwise acceleration (relative to g) of span station 4; Directed along the local xb3-axis
ElastoDyn['Spn4ALgyb3']       = False     # (m/s^2); Blade 3 local edgewise acceleration (relative to g) of span station 4; Directed along the local yb3-axis
ElastoDyn['Spn4ALgzb3']       = False     # (m/s^2); Blade 3 local axial acceleration (relative to g) of span station 4; Directed along the local zb3-axis
ElastoDyn['Spn5ALgxb3']       = False     # (m/s^2); Blade 3 local flapwise acceleration (relative to g) of span station 5; Directed along the local xb3-axis
ElastoDyn['Spn5ALgyb3']       = False     # (m/s^2); Blade 3 local edgewise acceleration (relative to g) of span station 5; Directed along the local yb3-axis
ElastoDyn['Spn5ALgzb3']       = False     # (m/s^2); Blade 3 local axial acceleration (relative to g) of span station 5; Directed along the local zb3-axis
ElastoDyn['Spn6ALgxb3']       = False     # (m/s^2); Blade 3 local flapwise acceleration (relative to g) of span station 6; Directed along the local xb3-axis
ElastoDyn['Spn6ALgyb3']       = False     # (m/s^2); Blade 3 local edgewise acceleration (relative to g) of span station 6; Directed along the local yb3-axis
ElastoDyn['Spn6ALgzb3']       = False     # (m/s^2); Blade 3 local axial acceleration (relative to g) of span station 6; Directed along the local zb3-axis
ElastoDyn['Spn7ALgxb3']       = False     # (m/s^2); Blade 3 local flapwise acceleration (relative to g) of span station 7; Directed along the local xb3-axis
ElastoDyn['Spn7ALgyb3']       = False     # (m/s^2); Blade 3 local edgewise acceleration (relative to g) of span station 7; Directed along the local yb3-axis
ElastoDyn['Spn7ALgzb3']       = False     # (m/s^2); Blade 3 local axial acceleration (relative to g) of span station 7; Directed along the local zb3-axis
ElastoDyn['Spn8ALgxb3']       = False     # (m/s^2); Blade 3 local flapwise acceleration (relative to g) of span station 8; Directed along the local xb3-axis
ElastoDyn['Spn8ALgyb3']       = False     # (m/s^2); Blade 3 local edgewise acceleration (relative to g) of span station 8; Directed along the local yb3-axis
ElastoDyn['Spn8ALgzb3']       = False     # (m/s^2); Blade 3 local axial acceleration (relative to g) of span station 8; Directed along the local zb3-axis
ElastoDyn['Spn9ALgxb3']       = False     # (m/s^2); Blade 3 local flapwise acceleration (relative to g) of span station 9; Directed along the local xb3-axis
ElastoDyn['Spn9ALgyb3']       = False     # (m/s^2); Blade 3 local edgewise acceleration (relative to g) of span station 9; Directed along the local yb3-axis
ElastoDyn['Spn9ALgzb3']       = False     # (m/s^2); Blade 3 local axial acceleration (relative to g) of span station 9; Directed along the local zb3-axis
ElastoDyn['Spn1TDxb3']        = False     # (m); Blade 3 local flapwise (translational) deflection (relative to the undeflected position) of span station 1; Directed along the xb3-axis
ElastoDyn['Spn1TDyb3']        = False     # (m); Blade 3 local edgewise (translational) deflection (relative to the undeflected position) of span station 1; Directed along the yb3-axis
ElastoDyn['Spn1TDzb3']        = False     # (m); Blade 3 local axial (translational) deflection (relative to the undeflected position) of span station 1; Directed along the zb3-axis
ElastoDyn['Spn2TDxb3']        = False     # (m); Blade 3 local flapwise (translational) deflection (relative to the undeflected position) of span station 2; Directed along the xb3-axis
ElastoDyn['Spn2TDyb3']        = False     # (m); Blade 3 local edgewise (translational) deflection (relative to the undeflected position) of span station 2; Directed along the yb3-axis
ElastoDyn['Spn2TDzb3']        = False     # (m); Blade 3 local axial (translational) deflection (relative to the undeflected position) of span station 2; Directed along the zb3-axis
ElastoDyn['Spn3TDxb3']        = False     # (m); Blade 3 local flapwise (translational) deflection (relative to the undeflected position) of span station 3; Directed along the xb3-axis
ElastoDyn['Spn3TDyb3']        = False     # (m); Blade 3 local edgewise (translational) deflection (relative to the undeflected position) of span station 3; Directed along the yb3-axis
ElastoDyn['Spn3TDzb3']        = False     # (m); Blade 3 local axial (translational) deflection (relative to the undeflected position) of span station 3; Directed along the zb3-axis
ElastoDyn['Spn4TDxb3']        = False     # (m); Blade 3 local flapwise (translational) deflection (relative to the undeflected position) of span station 4; Directed along the xb3-axis
ElastoDyn['Spn4TDyb3']        = False     # (m); Blade 3 local edgewise (translational) deflection (relative to the undeflected position) of span station 4; Directed along the yb3-axis
ElastoDyn['Spn4TDzb3']        = False     # (m); Blade 3 local axial (translational) deflection (relative to the undeflected position) of span station 4; Directed along the zb3-axis
ElastoDyn['Spn5TDxb3']        = False     # (m); Blade 3 local flapwise (translational) deflection (relative to the undeflected position) of span station 5; Directed along the xb3-axis
ElastoDyn['Spn5TDyb3']        = False     # (m); Blade 3 local edgewise (translational) deflection (relative to the undeflected position) of span station 5; Directed along the yb3-axis
ElastoDyn['Spn5TDzb3']        = False     # (m); Blade 3 local axial (translational) deflection (relative to the undeflected position) of span station 5; Directed along the zb3-axis
ElastoDyn['Spn6TDxb3']        = False     # (m); Blade 3 local flapwise (translational) deflection (relative to the undeflected position) of span station 6; Directed along the xb3-axis
ElastoDyn['Spn6TDyb3']        = False     # (m); Blade 3 local edgewise (translational) deflection (relative to the undeflected position) of span station 6; Directed along the yb3-axis
ElastoDyn['Spn6TDzb3']        = False     # (m); Blade 3 local axial (translational) deflection (relative to the undeflected position) of span station 6; Directed along the zb3-axis
ElastoDyn['Spn7TDxb3']        = False     # (m); Blade 3 local flapwise (translational) deflection (relative to the undeflected position) of span station 7; Directed along the xb3-axis
ElastoDyn['Spn7TDyb3']        = False     # (m); Blade 3 local edgewise (translational) deflection (relative to the undeflected position) of span station 7; Directed along the yb3-axis
ElastoDyn['Spn7TDzb3']        = False     # (m); Blade 3 local axial (translational) deflection (relative to the undeflected position) of span station 7; Directed along the zb3-axis
ElastoDyn['Spn8TDxb3']        = False     # (m); Blade 3 local flapwise (translational) deflection (relative to the undeflected position) of span station 8; Directed along the xb3-axis
ElastoDyn['Spn8TDyb3']        = False     # (m); Blade 3 local edgewise (translational) deflection (relative to the undeflected position) of span station 8; Directed along the yb3-axis
ElastoDyn['Spn8TDzb3']        = False     # (m); Blade 3 local axial (translational) deflection (relative to the undeflected position) of span station 8; Directed along the zb3-axis
ElastoDyn['Spn9TDxb3']        = False     # (m); Blade 3 local flapwise (translational) deflection (relative to the undeflected position) of span station 9; Directed along the xb3-axis
ElastoDyn['Spn9TDyb3']        = False     # (m); Blade 3 local edgewise (translational) deflection (relative to the undeflected position) of span station 9; Directed along the yb3-axis
ElastoDyn['Spn9TDzb3']        = False     # (m); Blade 3 local axial (translational) deflection (relative to the undeflected position) of span station 9; Directed along the zb3-axis
ElastoDyn['Spn1RDxb3']        = False     # (deg); Blade 3 local roll (angular/rotational)  deflection (relative to the undeflected position) of span station 1. In ADAMS, it is output as an Euler angle computed as the 3rd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the local xb3-axis
ElastoDyn['Spn1RDyb3']        = False     # (deg); Blade 3 local pitch (angular/rotational) deflection (relative to the undeflected position) of span station 1. In ADAMS, it is output as an Euler angle computed as the 2nd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the local yb3-axis
ElastoDyn['Spn1RDzb3']        = False     # (deg); Blade 3 local torsional (angular/rotational) deflection (relative to the undeflected position) of span station 1. This output will always be zero for FAST simulation results. Use it for examining blade torsional deflections of ADAMS simulations run using ADAMS datasets created using the FAST-to-ADAMS preprocessor. In ADAMS, it is output as an Euler angle computed as the 1st rotation in the yaw-pitch-roll rotation sequence.  Please note that this output uses the opposite of the sign convention used for blade pitch angles.; About the local zb3-axis
ElastoDyn['Spn2RDxb3']        = False     # (deg); Blade 3 local roll (angular/rotational)  deflection (relative to the undeflected position) of span station 2. In ADAMS, it is output as an Euler angle computed as the 3rd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the local xb3-axis
ElastoDyn['Spn2RDyb3']        = False     # (deg); Blade 3 local pitch (angular/rotational) deflection (relative to the undeflected position) of span station 2. In ADAMS, it is output as an Euler angle computed as the 2nd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the local yb3-axis
ElastoDyn['Spn2RDzb3']        = False     # (deg); Blade 3 local torsional (angular/rotational) deflection (relative to the undeflected position) of span station 2. This output will always be zero for FAST simulation results. Use it for examining blade torsional deflections of ADAMS simulations run using ADAMS datasets created using the FAST-to-ADAMS preprocessor. In ADAMS, it is output as an Euler angle computed as the 1st rotation in the yaw-pitch-roll rotation sequence.  Please note that this output uses the opposite of the sign convention used for blade pitch angles.; About the local zb3-axis
ElastoDyn['Spn3RDxb3']        = False     # (deg); Blade 3 local roll (angular/rotational)  deflection (relative to the undeflected position) of span station 3. In ADAMS, it is output as an Euler angle computed as the 3rd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the local xb3-axis
ElastoDyn['Spn3RDyb3']        = False     # (deg); Blade 3 local pitch (angular/rotational) deflection (relative to the undeflected position) of span station 3. In ADAMS, it is output as an Euler angle computed as the 2nd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the local yb3-axis
ElastoDyn['Spn3RDzb3']        = False     # (deg); Blade 3 local torsional (angular/rotational) deflection (relative to the undeflected position) of span station 3. This output will always be zero for FAST simulation results. Use it for examining blade torsional deflections of ADAMS simulations run using ADAMS datasets created using the FAST-to-ADAMS preprocessor. In ADAMS, it is output as an Euler angle computed as the 1st rotation in the yaw-pitch-roll rotation sequence.  Please note that this output uses the opposite of the sign convention used for blade pitch angles.; About the local zb3-axis
ElastoDyn['Spn4RDxb3']        = False     # (deg); Blade 3 local roll (angular/rotational)  deflection (relative to the undeflected position) of span station 4. In ADAMS, it is output as an Euler angle computed as the 3rd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the local xb3-axis
ElastoDyn['Spn4RDyb3']        = False     # (deg); Blade 3 local pitch (angular/rotational) deflection (relative to the undeflected position) of span station 4. In ADAMS, it is output as an Euler angle computed as the 2nd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the local yb3-axis
ElastoDyn['Spn4RDzb3']        = False     # (deg); Blade 3 local torsional (angular/rotational) deflection (relative to the undeflected position) of span station 4. This output will always be zero for FAST simulation results. Use it for examining blade torsional deflections of ADAMS simulations run using ADAMS datasets created using the FAST-to-ADAMS preprocessor. In ADAMS, it is output as an Euler angle computed as the 1st rotation in the yaw-pitch-roll rotation sequence.  Please note that this output uses the opposite of the sign convention used for blade pitch angles.; About the local zb3-axis
ElastoDyn['Spn5RDxb3']        = False     # (deg); Blade 3 local roll (angular/rotational)  deflection (relative to the undeflected position) of span station 5. In ADAMS, it is output as an Euler angle computed as the 3rd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the local xb3-axis
ElastoDyn['Spn5RDyb3']        = False     # (deg); Blade 3 local pitch (angular/rotational) deflection (relative to the undeflected position) of span station 5. In ADAMS, it is output as an Euler angle computed as the 2nd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the local yb3-axis
ElastoDyn['Spn5RDzb3']        = False     # (deg); Blade 3 local torsional (angular/rotational) deflection (relative to the undeflected position) of span station 5. This output will always be zero for FAST simulation results. Use it for examining blade torsional deflections of ADAMS simulations run using ADAMS datasets created using the FAST-to-ADAMS preprocessor. In ADAMS, it is output as an Euler angle computed as the 1st rotation in the yaw-pitch-roll rotation sequence.  Please note that this output uses the opposite of the sign convention used for blade pitch angles.; About the local zb3-axis
ElastoDyn['Spn6RDxb3']        = False     # (deg); Blade 3 local roll (angular/rotational)  deflection (relative to the undeflected position) of span station 6. In ADAMS, it is output as an Euler angle computed as the 3rd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the local xb3-axis
ElastoDyn['Spn6RDyb3']        = False     # (deg); Blade 3 local pitch (angular/rotational) deflection (relative to the undeflected position) of span station 6. In ADAMS, it is output as an Euler angle computed as the 2nd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the local yb3-axis
ElastoDyn['Spn6RDzb3']        = False     # (deg); Blade 3 local torsional (angular/rotational) deflection (relative to the undeflected position) of span station 6. This output will always be zero for FAST simulation results. Use it for examining blade torsional deflections of ADAMS simulations run using ADAMS datasets created using the FAST-to-ADAMS preprocessor. In ADAMS, it is output as an Euler angle computed as the 1st rotation in the yaw-pitch-roll rotation sequence.  Please note that this output uses the opposite of the sign convention used for blade pitch angles.; About the local zb3-axis
ElastoDyn['Spn7RDxb3']        = False     # (deg); Blade 3 local roll (angular/rotational)  deflection (relative to the undeflected position) of span station 7. In ADAMS, it is output as an Euler angle computed as the 3rd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the local xb3-axis
ElastoDyn['Spn7RDyb3']        = False     # (deg); Blade 3 local pitch (angular/rotational) deflection (relative to the undeflected position) of span station 7. In ADAMS, it is output as an Euler angle computed as the 2nd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the local yb3-axis
ElastoDyn['Spn7RDzb3']        = False     # (deg); Blade 3 local torsional (angular/rotational) deflection (relative to the undeflected position) of span station 7. This output will always be zero for FAST simulation results. Use it for examining blade torsional deflections of ADAMS simulations run using ADAMS datasets created using the FAST-to-ADAMS preprocessor. In ADAMS, it is output as an Euler angle computed as the 1st rotation in the yaw-pitch-roll rotation sequence.  Please note that this output uses the opposite of the sign convention used for blade pitch angles.; About the local zb3-axis
ElastoDyn['Spn8RDxb3']        = False     # (deg); Blade 3 local roll (angular/rotational)  deflection (relative to the undeflected position) of span station 8. In ADAMS, it is output as an Euler angle computed as the 3rd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the local xb3-axis
ElastoDyn['Spn8RDyb3']        = False     # (deg); Blade 3 local pitch (angular/rotational) deflection (relative to the undeflected position) of span station 8. In ADAMS, it is output as an Euler angle computed as the 2nd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the local yb3-axis
ElastoDyn['Spn8RDzb3']        = False     # (deg); Blade 3 local torsional (angular/rotational) deflection (relative to the undeflected position) of span station 8. This output will always be zero for FAST simulation results. Use it for examining blade torsional deflections of ADAMS simulations run using ADAMS datasets created using the FAST-to-ADAMS preprocessor. In ADAMS, it is output as an Euler angle computed as the 1st rotation in the yaw-pitch-roll rotation sequence.  Please note that this output uses the opposite of the sign convention used for blade pitch angles.; About the local zb3-axis
ElastoDyn['Spn9RDxb3']        = False     # (deg); Blade 3 local roll (angular/rotational)  deflection (relative to the undeflected position) of span station 9. In ADAMS, it is output as an Euler angle computed as the 3rd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the local xb3-axis
ElastoDyn['Spn9RDyb3']        = False     # (deg); Blade 3 local pitch (angular/rotational) deflection (relative to the undeflected position) of span station 9. In ADAMS, it is output as an Euler angle computed as the 2nd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small blade deflections, so that the rotation sequence does not matter.; About the local yb3-axis
ElastoDyn['Spn9RDzb3']        = False     # (deg); Blade 3 local torsional (angular/rotational) deflection (relative to the undeflected position) of span station 9. This output will always be zero for FAST simulation results. Use it for examining blade torsional deflections of ADAMS simulations run using ADAMS datasets created using the FAST-to-ADAMS preprocessor. In ADAMS, it is output as an Euler angle computed as the 1st rotation in the yaw-pitch-roll rotation sequence.  Please note that this output uses the opposite of the sign convention used for blade pitch angles.; About the local zb3-axis

# Blade Pitch Motions
ElastoDyn['PtchPMzc1']        = False     # (deg); Blade 1 pitch angle (position); Positive towards feather about the minus zc1- and minus zb1-axes
ElastoDyn['PtchPMzb1']        = False     # (deg); Blade 1 pitch angle (position); Positive towards feather about the minus zc1- and minus zb1-axes
ElastoDyn['BldPitch1']        = False     # (deg); Blade 1 pitch angle (position); Positive towards feather about the minus zc1- and minus zb1-axes
ElastoDyn['BlPitch1']         = False     # (deg); Blade 1 pitch angle (position); Positive towards feather about the minus zc1- and minus zb1-axes
ElastoDyn['PtchPMzc2']        = False     # (deg); Blade 2 pitch angle (position); Positive towards feather about the minus zc2- and minus zb2-axes
ElastoDyn['PtchPMzb2']        = False     # (deg); Blade 2 pitch angle (position); Positive towards feather about the minus zc2- and minus zb2-axes
ElastoDyn['BldPitch2']        = False     # (deg); Blade 2 pitch angle (position); Positive towards feather about the minus zc2- and minus zb2-axes
ElastoDyn['BlPitch2']         = False     # (deg); Blade 2 pitch angle (position); Positive towards feather about the minus zc2- and minus zb2-axes
ElastoDyn['PtchPMzc3']        = False     # (deg); Blade 3 pitch angle (position); Positive towards feather about the minus zc3- and minus zb3-axes
ElastoDyn['PtchPMzb3']        = False     # (deg); Blade 3 pitch angle (position); Positive towards feather about the minus zc3- and minus zb3-axes
ElastoDyn['BldPitch3']        = False     # (deg); Blade 3 pitch angle (position); Positive towards feather about the minus zc3- and minus zb3-axes
ElastoDyn['BlPitch3']         = False     # (deg); Blade 3 pitch angle (position); Positive towards feather about the minus zc3- and minus zb3-axes

# Teeter Motions
ElastoDyn['TeetPya']          = False     # (deg); Rotor teeter angle (position); About the ya-axis
ElastoDyn['RotTeetP']         = False     # (deg); Rotor teeter angle (position); About the ya-axis
ElastoDyn['TeetDefl']         = False     # (deg); Rotor teeter angle (position); About the ya-axis
ElastoDyn['TeetVya']          = False     # (deg/s); Rotor teeter angular velocity; About the ya-axis
ElastoDyn['RotTeetV']         = False     # (deg/s); Rotor teeter angular velocity; About the ya-axis
ElastoDyn['TeetAya']          = False     # (deg/s^2); Rotor teeter angular acceleration; About the ya-axis
ElastoDyn['RotTeetA']         = False     # (deg/s^2); Rotor teeter angular acceleration; About the ya-axis

# Shaft Motions
ElastoDyn['LSSTipPxa']        = False     # (deg); Rotor azimuth angle (position); About the xa- and xs-axes
ElastoDyn['LSSTipPxs']        = False     # (deg); Rotor azimuth angle (position); About the xa- and xs-axes
ElastoDyn['LSSTipP']          = False     # (deg); Rotor azimuth angle (position); About the xa- and xs-axes
ElastoDyn['Azimuth']          = False     # (deg); Rotor azimuth angle (position); About the xa- and xs-axes
ElastoDyn['LSSTipVxa']        = False     # (rpm); Rotor azimuth angular speed; About the xa- and xs-axes
ElastoDyn['LSSTipVxs']        = False     # (rpm); Rotor azimuth angular speed; About the xa- and xs-axes
ElastoDyn['LSSTipV']          = False     # (rpm); Rotor azimuth angular speed; About the xa- and xs-axes
ElastoDyn['RotSpeed']         = False     # (rpm); Rotor azimuth angular speed; About the xa- and xs-axes
ElastoDyn['LSSTipAxa']        = False     # (deg/s^2); Rotor azimuth angular acceleration; About the xa- and xs-axes
ElastoDyn['LSSTipAxs']        = False     # (deg/s^2); Rotor azimuth angular acceleration; About the xa- and xs-axes
ElastoDyn['LSSTipA']          = False     # (deg/s^2); Rotor azimuth angular acceleration; About the xa- and xs-axes
ElastoDyn['RotAccel']         = False     # (deg/s^2); Rotor azimuth angular acceleration; About the xa- and xs-axes
ElastoDyn['LSSGagPxa']        = False     # (deg); Low-speed shaft strain gage azimuth angle (position) (on the gearbox side of the low-speed shaft); About the xa- and xs-axes
ElastoDyn['LSSGagPxs']        = False     # (deg); Low-speed shaft strain gage azimuth angle (position) (on the gearbox side of the low-speed shaft); About the xa- and xs-axes
ElastoDyn['LSSGagP']          = False     # (deg); Low-speed shaft strain gage azimuth angle (position) (on the gearbox side of the low-speed shaft); About the xa- and xs-axes
ElastoDyn['LSSGagVxa']        = False     # (rpm); Low-speed shaft strain gage angular speed (on the gearbox side of the low-speed shaft); About the xa- and xs-axes
ElastoDyn['LSSGagVxs']        = False     # (rpm); Low-speed shaft strain gage angular speed (on the gearbox side of the low-speed shaft); About the xa- and xs-axes
ElastoDyn['LSSGagV']          = False     # (rpm); Low-speed shaft strain gage angular speed (on the gearbox side of the low-speed shaft); About the xa- and xs-axes
ElastoDyn['LSSGagAxa']        = False     # (deg/s^2); Low-speed shaft strain gage angular acceleration (on the gearbox side of the low-speed shaft); About the xa- and xs-axes
ElastoDyn['LSSGagAxs']        = False     # (deg/s^2); Low-speed shaft strain gage angular acceleration (on the gearbox side of the low-speed shaft); About the xa- and xs-axes
ElastoDyn['LSSGagA']          = False     # (deg/s^2); Low-speed shaft strain gage angular acceleration (on the gearbox side of the low-speed shaft); About the xa- and xs-axes
ElastoDyn['HSShftV']          = False     # (rpm); Angular speed of the high-speed shaft and generator; Same sign as LSSGagVxa / LSSGagVxs / LSSGagV
ElastoDyn['GenSpeed']         = False     # (rpm); Angular speed of the high-speed shaft and generator; Same sign as LSSGagVxa / LSSGagVxs / LSSGagV
ElastoDyn['HSShftA']          = False     # (deg/s^2); Angular acceleration of the high-speed shaft and generator; Same sign as LSSGagAxa / LSSGagAxs / LSSGagA
ElastoDyn['GenAccel']         = False     # (deg/s^2); Angular acceleration of the high-speed shaft and generator; Same sign as LSSGagAxa / LSSGagAxs / LSSGagA

# Nacelle IMU Motions
ElastoDyn['NcIMUTVxs']        = False     # (m/s); Nacelle inertial measurement unit translational velocity (absolute); Directed along the xs-axis
ElastoDyn['NcIMUTVys']        = False     # (m/s); Nacelle inertial measurement unit translational velocity (absolute); Directed along the ys-axis
ElastoDyn['NcIMUTVzs']        = False     # (m/s); Nacelle inertial measurement unit translational velocity (absolute); Directed along the zs-axis
ElastoDyn['NcIMUTAxs']        = False     # (m/s^2); Nacelle inertial measurement unit translational acceleration (absolute); Directed along the xs-axis
ElastoDyn['NcIMUTAys']        = False     # (m/s^2); Nacelle inertial measurement unit translational acceleration (absolute); Directed along the ys-axis
ElastoDyn['NcIMUTAzs']        = False     # (m/s^2); Nacelle inertial measurement unit translational acceleration (absolute); Directed along the zs-axis
ElastoDyn['NcIMUTAgxs']       = False     # (m/s^2); Nacelle inertial measurement unit translational acceleration (relative to g); Directed along the xs-axis
ElastoDyn['NcIMUTAgys']       = False     # (m/s^2); Nacelle inertial measurement unit translational acceleration (relative to g); Directed along the ys-axis
ElastoDyn['NcIMUTAgzs']       = False     # (m/s^2); Nacelle inertial measurement unit translational acceleration (relative to g); Directed along the zs-axis
ElastoDyn['NcIMURVxs']        = False     # (deg/s); Nacelle inertial measurement unit angular (rotational) velocity (absolute); About the xs-axis
ElastoDyn['NcIMURVys']        = False     # (deg/s); Nacelle inertial measurement unit angular (rotational) velocity (absolute); About the ys-axis
ElastoDyn['NcIMURVzs']        = False     # (deg/s); Nacelle inertial measurement unit angular (rotational) velocity (absolute); About the zs-axis
ElastoDyn['NcIMURAxs']        = False     # (deg/s^2); Nacelle inertial measurement unit angular (rotational) acceleration (absolute); About the xs-axis
ElastoDyn['NcIMURAys']        = False     # (deg/s^2); Nacelle inertial measurement unit angular (rotational) acceleration (absolute); About the ys-axis
ElastoDyn['NcIMURAzs']        = False     # (deg/s^2); Nacelle inertial measurement unit angular (rotational) acceleration (absolute); About the zs-axis

# Rotor-Furl Motions
ElastoDyn['RotFurlP']         = False     # (deg); Rotor-furl angle (position); About the rotor-furl axis
ElastoDyn['RotFurl']          = False     # (deg); Rotor-furl angle (position); About the rotor-furl axis
ElastoDyn['RotFurlV']         = False     # (deg/s); Rotor-furl angular velocity; About the rotor-furl axis
ElastoDyn['RotFurlA']         = False     # (deg/s^2); Rotor-furl angular acceleration; About the rotor-furl axis

# Tail-Furl Motions
ElastoDyn['TailFurlP']        = False     # (deg); Tail-furl angle (position); About the tail-furl axis
ElastoDyn['TailFurl']         = False     # (deg); Tail-furl angle (position); About the tail-furl axis
ElastoDyn['TailFurlV']        = False     # (deg/s); Tail-furl angular velocity; About the tail-furl axis
ElastoDyn['TailFurlA']        = False     # (deg/s^2); Tail-furl angular acceleration; About the tail-furl axis

# Nacelle Yaw Motions
ElastoDyn['YawPzn']           = False     # (deg); Nacelle yaw angle (position); About the zn- and zp-axes
ElastoDyn['YawPzp']           = False     # (deg); Nacelle yaw angle (position); About the zn- and zp-axes
ElastoDyn['NacYawP']          = False     # (deg); Nacelle yaw angle (position); About the zn- and zp-axes
ElastoDyn['NacYaw']           = False     # (deg); Nacelle yaw angle (position); About the zn- and zp-axes
ElastoDyn['YawPos']           = False     # (deg); Nacelle yaw angle (position); About the zn- and zp-axes
ElastoDyn['YawVzn']           = False     # (deg/s); Nacelle yaw angular velocity; About the zn- and zp-axes
ElastoDyn['YawVzp']           = False     # (deg/s); Nacelle yaw angular velocity; About the zn- and zp-axes
ElastoDyn['NacYawV']          = False     # (deg/s); Nacelle yaw angular velocity; About the zn- and zp-axes
ElastoDyn['YawRate']          = False     # (deg/s); Nacelle yaw angular velocity; About the zn- and zp-axes
ElastoDyn['YawAzn']           = False     # (deg/s^2); Nacelle yaw angular acceleration; About the zn- and zp-axes
ElastoDyn['YawAzp']           = False     # (deg/s^2); Nacelle yaw angular acceleration; About the zn- and zp-axes
ElastoDyn['NacYawA']          = False     # (deg/s^2); Nacelle yaw angular acceleration; About the zn- and zp-axes
ElastoDyn['YawAccel']         = False     # (deg/s^2); Nacelle yaw angular acceleration; About the zn- and zp-axes

# Tower-Top / Yaw Bearing Motions
ElastoDyn['TwrTpTDxi']        = False     # (m); Tower-top / yaw bearing fore-aft (translational) deflection (relative to the undeflected position) including all platform motions; Directed along the xi-axis
ElastoDyn['YawBrTDxi']        = False     # (m); Tower-top / yaw bearing fore-aft (translational) deflection (relative to the undeflected position) including all platform motions; Directed along the xi-axis
ElastoDyn['TwrTpTDyi']        = False     # (m); Tower-top / yaw bearing side-to-side (translational) deflection (relative to the undeflected position) including all platform motions; Directed along the yi-axis
ElastoDyn['YawBrTDyi']        = False     # (m); Tower-top / yaw bearing side-to-side (translational) deflection (relative to the undeflected position) including all platform motions; Directed along the yi-axis
ElastoDyn['TwrTpTDzi']        = False     # (m); Tower-top / yaw bearing axial (translational) deflection (relative to the undeflected position) including all platform motions; Directed along the zi-axis
ElastoDyn['YawBrTDzi']        = False     # (m); Tower-top / yaw bearing axial (translational) deflection (relative to the undeflected position) including all platform motions; Directed along the zi-axis
ElastoDyn['YawBrTDxp']        = False     # (m); Tower-top / yaw bearing fore-aft (translational) deflection (relative to the undeflected position); Directed along the xp-axis
ElastoDyn['YawBrTDyp']        = False     # (m); Tower-top / yaw bearing side-to-side (translational) deflection (relative to the undeflected position); Directed along the yp-axis
ElastoDyn['YawBrTDzp']        = False     # (m); Tower-top / yaw bearing axial (translational) deflection (relative to the undeflected position); Directed along the zp-axis
ElastoDyn['YawBrTDxt']        = False     # (m); Tower-top / yaw bearing fore-aft (translational) deflection (relative to the undeflected position); Directed along the xt-axis
ElastoDyn['TTDspFA']          = False     # (m); Tower-top / yaw bearing fore-aft (translational) deflection (relative to the undeflected position); Directed along the xt-axis
ElastoDyn['YawBrTDyt']        = False     # (m); Tower-top / yaw bearing side-to-side (translation) deflection (relative to the undeflected position); Directed along the yt-axis
ElastoDyn['TTDspSS']          = False     # (m); Tower-top / yaw bearing side-to-side (translation) deflection (relative to the undeflected position); Directed along the yt-axis
ElastoDyn['YawBrTDzt']        = False     # (m); Tower-top / yaw bearing axial (translational) deflection (relative to the undeflected position); Directed along the zt-axis
ElastoDyn['TTDspAx']          = False     # (m); Tower-top / yaw bearing axial (translational) deflection (relative to the undeflected position); Directed along the zt-axis
ElastoDyn['YawBrTVxp']        = False     # (m/s); Tower-top / yaw bearing fore-aft (translational) velocity (absolute); Directed along the xp-axis
ElastoDyn['YawBrTVyp']        = False     # (m/s); Tower-top / yaw bearing side-to-side (translational) velocity (absolute); Directed along the yp-axis
ElastoDyn['YawBrTVzp']        = False     # (m/s); Tower-top / yaw bearing axial (translational) velocity (absolute); Directed along the zp-axis
ElastoDyn['YawBrTAxp']        = False     # (m/s^2); Tower-top / yaw bearing fore-aft (translational) acceleration (absolute); Directed along the xp-axis
ElastoDyn['YawBrTAyp']        = False     # (m/s^2); Tower-top / yaw bearing side-to-side (translational) acceleration (absolute); Directed along the yp-axis
ElastoDyn['YawBrTAzp']        = False     # (m/s^2); Tower-top / yaw bearing axial (translational) acceleration (absolute); Directed along the zp-axis
ElastoDyn['YawBrTAgxp']       = False     # (m/s^2); Tower-top / yaw bearing fore-aft (translational) acceleration (relative to g); Directed along the xp-axis
ElastoDyn['YawBrTAgyp']       = False     # (m/s^2); Tower-top / yaw bearing side-to-side (translational) acceleration (relative to g); Directed along the yp-axis
ElastoDyn['YawBrTAgzp']       = False     # (m/s^2); Tower-top / yaw bearing axial (translational) acceleration (relative to g); Directed along the zp-axis
ElastoDyn['YawBrRDxt']        = False     # (deg); Tower-top / yaw bearing angular (rotational) roll deflection (relative to the undeflected position). In ADAMS, it is output as an Euler angle computed as the 3rd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small tower deflections, so that the rotation sequence does not matter.; About the xt-axis
ElastoDyn['TTDspRoll']        = False     # (deg); Tower-top / yaw bearing angular (rotational) roll deflection (relative to the undeflected position). In ADAMS, it is output as an Euler angle computed as the 3rd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small tower deflections, so that the rotation sequence does not matter.; About the xt-axis
ElastoDyn['YawBrRDyt']        = False     # (deg); Tower-top / yaw bearing angular (rotational) pitch deflection (relative to the undeflected position). In ADAMS, it is output as an Euler angle computed as the 2nd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small tower deflections, so that the rotation sequence does not matter.; About the yt-axis
ElastoDyn['TTDspPtch']        = False     # (deg); Tower-top / yaw bearing angular (rotational) pitch deflection (relative to the undeflected position). In ADAMS, it is output as an Euler angle computed as the 2nd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small tower deflections, so that the rotation sequence does not matter.; About the yt-axis
ElastoDyn['YawBrRDzt']        = False     # (deg); Tower-top / yaw bearing angular (rotational) torsion deflection (relative to the undeflected position). This output will always be zero for FAST simulation results. Use it for examining tower torsional deflections of ADAMS simulations run using ADAMS datasets created using the FAST-to-ADAMS preprocessor. In ADAMS, it is output as an Euler angle computed as the 1st rotation in the yaw-pitch-roll rotation sequence.; About the zt-axis
ElastoDyn['TTDspTwst']        = False     # (deg); Tower-top / yaw bearing angular (rotational) torsion deflection (relative to the undeflected position). This output will always be zero for FAST simulation results. Use it for examining tower torsional deflections of ADAMS simulations run using ADAMS datasets created using the FAST-to-ADAMS preprocessor. In ADAMS, it is output as an Euler angle computed as the 1st rotation in the yaw-pitch-roll rotation sequence.; About the zt-axis
ElastoDyn['YawBrRVxp']        = False     # (deg/s); Tower-top / yaw bearing angular (rotational) roll velocity (absolute); About the xp-axis
ElastoDyn['YawBrRVyp']        = False     # (deg/s); Tower-top / yaw bearing angular (rotational) pitch velocity (absolute); About the yp-axis
ElastoDyn['YawBrRVzp']        = False     # (deg/s); Tower-top / yaw bearing angular (rotational) torsion velocity. This output will always be very close to zero for FAST simulation results. Use it for examining tower torsional deflections of ADAMS simulations run using ADAMS datasets created using the FAST-to-ADAMS preprocessor. (absolute); About the zp-axis
ElastoDyn['YawBrRAxp']        = False     # (deg/s^2); Tower-top / yaw bearing angular (rotational) roll acceleration (absolute); About the xp-axis
ElastoDyn['YawBrRAyp']        = False     # (deg/s^2); Tower-top / yaw bearing angular (rotational) pitch acceleration (absolute); About the yp-axis
ElastoDyn['YawBrRAzp']        = False     # (deg/s^2); Tower-top / yaw bearing angular (rotational) torsion acceleration. This output will always be very close to zero for FAST simulation results. Use it for examining tower torsional deflections of ADAMS simulations run using ADAMS datasets created using the FAST-to-ADAMS preprocessor. (absolute); About the zp-axis

# Local Tower Motions
ElastoDyn['TwHt1ALxt']        = False     # (m/s^2); Local tower fore-aft (translational) acceleration (absolute) of tower gage 1 ; Directed along the local xt-axis
ElastoDyn['TwHt1ALyt']        = False     # (m/s^2); Local tower side-to-side (translational) acceleration (absolute) of tower gage 1 ; Directed along the local yt-axis
ElastoDyn['TwHt1ALzt']        = False     # (m/s^2); Local tower axial (translational) acceleration (absolute) of tower gage 1 ; Directed along the local zt-axis
ElastoDyn['TwHt2ALxt']        = False     # (m/s^2); Local tower fore-aft (translational) acceleration (absolute) of tower gage 2; Directed along the local xt-axis
ElastoDyn['TwHt2ALyt']        = False     # (m/s^2); Local tower side-to-side (translational) acceleration (absolute) of tower gage 2; Directed along the local yt-axis
ElastoDyn['TwHt2ALzt']        = False     # (m/s^2); Local tower axial (translational) acceleration (absolute) of tower gage 2; Directed along the local zt-axis
ElastoDyn['TwHt3ALxt']        = False     # (m/s^2); Local tower fore-aft (translational) acceleration (absolute) of tower gage 3; Directed along the local xt-axis
ElastoDyn['TwHt3ALyt']        = False     # (m/s^2); Local tower side-to-side (translational) acceleration (absolute) of tower gage 3; Directed along the local yt-axis
ElastoDyn['TwHt3ALzt']        = False     # (m/s^2); Local tower axial (translational) acceleration (absolute) of tower gage 3; Directed along the local zt-axis
ElastoDyn['TwHt4ALxt']        = False     # (m/s^2); Local tower fore-aft (translational) acceleration (absolute) of tower gage 4; Directed along the local xt-axis
ElastoDyn['TwHt4ALyt']        = False     # (m/s^2); Local tower side-to-side (translational) acceleration (absolute) of tower gage 4; Directed along the local yt-axis
ElastoDyn['TwHt4ALzt']        = False     # (m/s^2); Local tower axial (translational) acceleration (absolute) of tower gage 4; Directed along the local zt-axis
ElastoDyn['TwHt5ALxt']        = False     # (m/s^2); Local tower fore-aft (translational) acceleration (absolute) of tower gage 5; Directed along the local xt-axis
ElastoDyn['TwHt5ALyt']        = False     # (m/s^2); Local tower side-to-side (translational) acceleration (absolute) of tower gage 5; Directed along the local yt-axis
ElastoDyn['TwHt5ALzt']        = False     # (m/s^2); Local tower axial (translational) acceleration (absolute) of tower gage 5; Directed along the local zt-axis
ElastoDyn['TwHt6ALxt']        = False     # (m/s^2); Local tower fore-aft (translational) acceleration (absolute) of tower gage 6; Directed along the local xt-axis
ElastoDyn['TwHt6ALyt']        = False     # (m/s^2); Local tower side-to-side (translational) acceleration (absolute) of tower gage 6; Directed along the local yt-axis
ElastoDyn['TwHt6ALzt']        = False     # (m/s^2); Local tower axial (translational) acceleration (absolute) of tower gage 6; Directed along the local zt-axis
ElastoDyn['TwHt7ALxt']        = False     # (m/s^2); Local tower fore-aft (translational) acceleration (absolute) of tower gage 7; Directed along the local xt-axis
ElastoDyn['TwHt7ALyt']        = False     # (m/s^2); Local tower side-to-side (translational) acceleration (absolute) of tower gage 7; Directed along the local yt-axis
ElastoDyn['TwHt7ALzt']        = False     # (m/s^2); Local tower axial (translational) acceleration (absolute) of tower gage 7; Directed along the local zt-axis
ElastoDyn['TwHt8ALxt']        = False     # (m/s^2); Local tower fore-aft (translational) acceleration (absolute) of tower gage 8; Directed along the local xt-axis
ElastoDyn['TwHt8ALyt']        = False     # (m/s^2); Local tower side-to-side (translational) acceleration (absolute) of tower gage 8; Directed along the local yt-axis
ElastoDyn['TwHt8ALzt']        = False     # (m/s^2); Local tower axial (translational) acceleration (absolute) of tower gage 8; Directed along the local zt-axis
ElastoDyn['TwHt9ALxt']        = False     # (m/s^2); Local tower fore-aft (translational) acceleration (absolute) of tower gage 9; Directed along the local xt-axis
ElastoDyn['TwHt9ALyt']        = False     # (m/s^2); Local tower side-to-side (translational) acceleration (absolute) of tower gage 9; Directed along the local yt-axis
ElastoDyn['TwHt9ALzt']        = False     # (m/s^2); Local tower axial (translational) acceleration (absolute) of tower gage 9; Directed along the local zt-axis
ElastoDyn['TwHt1ALgxt']       = False     # (m/s^2); Local tower fore-aft (translational) acceleration (relative to g) of tower gage 1 ; Directed along the local xt-axis
ElastoDyn['TwHt1ALgyt']       = False     # (m/s^2); Local tower side-to-side (translational) acceleration (relative to g) of tower gage 1 ; Directed along the local yt-axis
ElastoDyn['TwHt1ALgzt']       = False     # (m/s^2); Local tower axial (translational) acceleration (relative to g) of tower gage 1 ; Directed along the local zt-axis
ElastoDyn['TwHt2ALgxt']       = False     # (m/s^2); Local tower fore-aft (translational) acceleration (relative to g) of tower gage 2; Directed along the local xt-axis
ElastoDyn['TwHt2ALgyt']       = False     # (m/s^2); Local tower side-to-side (translational) acceleration (relative to g) of tower gage 2; Directed along the local yt-axis
ElastoDyn['TwHt2ALgzt']       = False     # (m/s^2); Local tower axial (translational) acceleration (relative to g) of tower gage 2; Directed along the local zt-axis
ElastoDyn['TwHt3ALgxt']       = False     # (m/s^2); Local tower fore-aft (translational) acceleration (relative to g) of tower gage 3; Directed along the local xt-axis
ElastoDyn['TwHt3ALgyt']       = False     # (m/s^2); Local tower side-to-side (translational) acceleration (relative to g) of tower gage 3; Directed along the local yt-axis
ElastoDyn['TwHt3ALgzt']       = False     # (m/s^2); Local tower axial (translational) acceleration (relative to g) of tower gage 3; Directed along the local zt-axis
ElastoDyn['TwHt4ALgxt']       = False     # (m/s^2); Local tower fore-aft (translational) acceleration (relative to g) of tower gage 4; Directed along the local xt-axis
ElastoDyn['TwHt4ALgyt']       = False     # (m/s^2); Local tower side-to-side (translational) acceleration (relative to g) of tower gage 4; Directed along the local yt-axis
ElastoDyn['TwHt4ALgzt']       = False     # (m/s^2); Local tower axial (translational) acceleration (relative to g) of tower gage 4; Directed along the local zt-axis
ElastoDyn['TwHt5ALgxt']       = False     # (m/s^2); Local tower fore-aft (translational) acceleration (relative to g) of tower gage 5; Directed along the local xt-axis
ElastoDyn['TwHt5ALgyt']       = False     # (m/s^2); Local tower side-to-side (translational) acceleration (relative to g) of tower gage 5; Directed along the local yt-axis
ElastoDyn['TwHt5ALgzt']       = False     # (m/s^2); Local tower axial (translational) acceleration (relative to g) of tower gage 5; Directed along the local zt-axis
ElastoDyn['TwHt6ALgxt']       = False     # (m/s^2); Local tower fore-aft (translational) acceleration (relative to g) of tower gage 6; Directed along the local xt-axis
ElastoDyn['TwHt6ALgyt']       = False     # (m/s^2); Local tower side-to-side (translational) acceleration (relative to g) of tower gage 6; Directed along the local yt-axis
ElastoDyn['TwHt6ALgzt']       = False     # (m/s^2); Local tower axial (translational) acceleration (relative to g) of tower gage 6; Directed along the local zt-axis
ElastoDyn['TwHt7ALgxt']       = False     # (m/s^2); Local tower fore-aft (translational) acceleration (relative to g) of tower gage 7; Directed along the local xt-axis
ElastoDyn['TwHt7ALgyt']       = False     # (m/s^2); Local tower side-to-side (translational) acceleration (relative to g) of tower gage 7; Directed along the local yt-axis
ElastoDyn['TwHt7ALgzt']       = False     # (m/s^2); Local tower axial (translational) acceleration (relative to g) of tower gage 7; Directed along the local zt-axis
ElastoDyn['TwHt8ALgxt']       = False     # (m/s^2); Local tower fore-aft (translational) acceleration (relative to g) of tower gage 8; Directed along the local xt-axis
ElastoDyn['TwHt8ALgyt']       = False     # (m/s^2); Local tower side-to-side (translational) acceleration (relative to g) of tower gage 8; Directed along the local yt-axis
ElastoDyn['TwHt8ALgzt']       = False     # (m/s^2); Local tower axial (translational) acceleration (relative to g) of tower gage 8; Directed along the local zt-axis
ElastoDyn['TwHt9ALgxt']       = False     # (m/s^2); Local tower fore-aft (translational) acceleration (relative to g) of tower gage 9; Directed along the local xt-axis
ElastoDyn['TwHt9ALgyt']       = False     # (m/s^2); Local tower side-to-side (translational) acceleration (relative to g) of tower gage 9; Directed along the local yt-axis
ElastoDyn['TwHt9ALgzt']       = False     # (m/s^2); Local tower axial (translational) acceleration (relative to g) of tower gage 9; Directed along the local zt-axis
ElastoDyn['TwHt1TDxt']        = False     # (m); Local tower fore-aft (translational) deflection (relative to the undeflected position) of tower gage 1; Directed along the local xt-axis
ElastoDyn['TwHt1TDyt']        = False     # (m); Local tower side-to-side (translational) deflection (relative to the undeflected position) of tower gage 1; Directed along the local yt-axis
ElastoDyn['TwHt1TDzt']        = False     # (m); Local tower axial (translational) deflection (relative to the undeflected position) of tower gage 1; Directed along the local zt-axis
ElastoDyn['TwHt2TDxt']        = False     # (m); Local tower fore-aft (translational) deflection (relative to the undeflected position) of tower gage 2; Directed along the local xt-axis
ElastoDyn['TwHt2TDyt']        = False     # (m); Local tower side-to-side (translational) deflection (relative to the undeflected position) of tower gage 2; Directed along the local yt-axis
ElastoDyn['TwHt2TDzt']        = False     # (m); Local tower axial (translational) deflection (relative to the undeflected position) of tower gage 2; Directed along the local zt-axis
ElastoDyn['TwHt3TDxt']        = False     # (m); Local tower fore-aft (translational) deflection (relative to the undeflected position) of tower gage 3; Directed along the local xt-axis
ElastoDyn['TwHt3TDyt']        = False     # (m); Local tower side-to-side (translational) deflection (relative to the undeflected position) of tower gage 3; Directed along the local yt-axis
ElastoDyn['TwHt3TDzt']        = False     # (m); Local tower axial (translational) deflection (relative to the undeflected position) of tower gage 3; Directed along the local zt-axis
ElastoDyn['TwHt4TDxt']        = False     # (m); Local tower fore-aft (translational) deflection (relative to the undeflected position) of tower gage 4; Directed along the local xt-axis
ElastoDyn['TwHt4TDyt']        = False     # (m); Local tower side-to-side (translational) deflection (relative to the undeflected position) of tower gage 4; Directed along the local yt-axis
ElastoDyn['TwHt4TDzt']        = False     # (m); Local tower axial (translational) deflection (relative to the undeflected position) of tower gage 4; Directed along the local zt-axis
ElastoDyn['TwHt5TDxt']        = False     # (m); Local tower fore-aft (translational) deflection (relative to the undeflected position) of tower gage 5; Directed along the local xt-axis
ElastoDyn['TwHt5TDyt']        = False     # (m); Local tower side-to-side (translational) deflection (relative to the undeflected position) of tower gage 5; Directed along the local yt-axis
ElastoDyn['TwHt5TDzt']        = False     # (m); Local tower axial (translational) deflection (relative to the undeflected position) of tower gage 5; Directed along the local zt-axis
ElastoDyn['TwHt6TDxt']        = False     # (m); Local tower fore-aft (translational) deflection (relative to the undeflected position) of tower gage 6; Directed along the local xt-axis
ElastoDyn['TwHt6TDyt']        = False     # (m); Local tower side-to-side (translational) deflection (relative to the undeflected position) of tower gage 6; Directed along the local yt-axis
ElastoDyn['TwHt6TDzt']        = False     # (m); Local tower axial (translational) deflection (relative to the undeflected position) of tower gage 6; Directed along the local zt-axis
ElastoDyn['TwHt7TDxt']        = False     # (m); Local tower fore-aft (translational) deflection (relative to the undeflected position) of tower gage 7; Directed along the local xt-axis
ElastoDyn['TwHt7TDyt']        = False     # (m); Local tower side-to-side (translational) deflection (relative to the undeflected position) of tower gage 7; Directed along the local yt-axis
ElastoDyn['TwHt7TDzt']        = False     # (m); Local tower axial (translational) deflection (relative to the undeflected position) of tower gage 7; Directed along the local zt-axis
ElastoDyn['TwHt8TDxt']        = False     # (m); Local tower fore-aft (translational) deflection (relative to the undeflected position) of tower gage 8; Directed along the local xt-axis
ElastoDyn['TwHt8TDyt']        = False     # (m); Local tower side-to-side (translational) deflection (relative to the undeflected position) of tower gage 8; Directed along the local yt-axis
ElastoDyn['TwHt8TDzt']        = False     # (m); Local tower axial (translational) deflection (relative to the undeflected position) of tower gage 8; Directed along the local zt-axis
ElastoDyn['TwHt9TDxt']        = False     # (m); Local tower fore-aft (translational) deflection (relative to the undeflected position) of tower gage 9; Directed along the local xt-axis
ElastoDyn['TwHt9TDyt']        = False     # (m); Local tower side-to-side (translational) deflection (relative to the undeflected position) of tower gage 9; Directed along the local yt-axis
ElastoDyn['TwHt9TDzt']        = False     # (m); Local tower axial (translational) deflection (relative to the undeflected position) of tower gage 9; Directed along the local zt-axis
ElastoDyn['TwHt1RDxt']        = False     # (deg); Local tower angular (rotational) roll deflection (relative to the undeflected position) of tower gage 1. In ADAMS, it is output as an Euler angle computed as the 3rd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small tower deflections, so that the rotation sequence does not matter.; About the local xt-axis
ElastoDyn['TwHt1RDyt']        = False     # (deg); Local tower angular (rotational) pitch deflection (relative to the undeflected position) of tower gage 1. In ADAMS, it is output as an Euler angle computed as the 2nd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small tower deflections, so that the rotation sequence does not matter.; About the local yt-axis
ElastoDyn['TwHt1RDzt']        = False     # (deg); Local tower angular (rotational) torsion deflection (relative to the undeflected position) of tower gage 1. This output will always be zero for FAST simulation results. Use it for examining tower torsional deflections of ADAMS simulations run using ADAMS datasets created using the FAST-to-ADAMS preprocessor. In ADAMS, it is output as an Euler angle computed as the 1st rotation in the yaw-pitch-roll rotation sequence.; About the local zt-axis
ElastoDyn['TwHt2RDxt']        = False     # (deg); Local tower angular (rotational) roll deflection (relative to the undeflected position) of tower gage 2. In ADAMS, it is output as an Euler angle computed as the 3rd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small tower deflections, so that the rotation sequence does not matter.; About the local xt-axis
ElastoDyn['TwHt2RDyt']        = False     # (deg); Local tower angular (rotational) pitch deflection (relative to the undeflected position) of tower gage 2. In ADAMS, it is output as an Euler angle computed as the 2nd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small tower deflections, so that the rotation sequence does not matter.; About the local yt-axis
ElastoDyn['TwHt2RDzt']        = False     # (deg); Local tower angular (rotational) torsion deflection (relative to the undeflected position) of tower gage 2. This output will always be zero for FAST simulation results. Use it for examining tower torsional deflections of ADAMS simulations run using ADAMS datasets created using the FAST-to-ADAMS preprocessor. In ADAMS, it is output as an Euler angle computed as the 1st rotation in the yaw-pitch-roll rotation sequence.; About the local zt-axis
ElastoDyn['TwHt3RDxt']        = False     # (deg); Local tower angular (rotational) roll deflection (relative to the undeflected position) of tower gage 3. In ADAMS, it is output as an Euler angle computed as the 3rd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small tower deflections, so that the rotation sequence does not matter.; About the local xt-axis
ElastoDyn['TwHt3RDyt']        = False     # (deg); Local tower angular (rotational) pitch deflection (relative to the undeflected position) of tower gage 3. In ADAMS, it is output as an Euler angle computed as the 2nd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small tower deflections, so that the rotation sequence does not matter.; About the local yt-axis
ElastoDyn['TwHt3RDzt']        = False     # (deg); Local tower angular (rotational) torsion deflection (relative to the undeflected position) of tower gage 3. This output will always be zero for FAST simulation results. Use it for examining tower torsional deflections of ADAMS simulations run using ADAMS datasets created using the FAST-to-ADAMS preprocessor. In ADAMS, it is output as an Euler angle computed as the 1st rotation in the yaw-pitch-roll rotation sequence.; About the local zt-axis
ElastoDyn['TwHt4RDxt']        = False     # (deg); Local tower angular (rotational) roll deflection (relative to the undeflected position) of tower gage 4. In ADAMS, it is output as an Euler angle computed as the 3rd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small tower deflections, so that the rotation sequence does not matter.; About the local xt-axis
ElastoDyn['TwHt4RDyt']        = False     # (deg); Local tower angular (rotational) pitch deflection (relative to the undeflected position) of tower gage 4. In ADAMS, it is output as an Euler angle computed as the 2nd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small tower deflections, so that the rotation sequence does not matter.; About the local yt-axis
ElastoDyn['TwHt4RDzt']        = False     # (deg); Local tower angular (rotational) torsion deflection (relative to the undeflected position) of tower gage 4. This output will always be zero for FAST simulation results. Use it for examining tower torsional deflections of ADAMS simulations run using ADAMS datasets created using the FAST-to-ADAMS preprocessor. In ADAMS, it is output as an Euler angle computed as the 1st rotation in the yaw-pitch-roll rotation sequence.; About the local zt-axis
ElastoDyn['TwHt5RDxt']        = False     # (deg); Local tower angular (rotational) roll deflection (relative to the undeflected position) of tower gage 5. In ADAMS, it is output as an Euler angle computed as the 3rd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small tower deflections, so that the rotation sequence does not matter.; About the local xt-axis
ElastoDyn['TwHt5RDyt']        = False     # (deg); Local tower angular (rotational) pitch deflection (relative to the undeflected position) of tower gage 5. In ADAMS, it is output as an Euler angle computed as the 2nd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small tower deflections, so that the rotation sequence does not matter.; About the local yt-axis
ElastoDyn['TwHt5RDzt']        = False     # (deg); Local tower angular (rotational) torsion deflection (relative to the undeflected position) of tower gage 5. This output will always be zero for FAST simulation results. Use it for examining tower torsional deflections of ADAMS simulations run using ADAMS datasets created using the FAST-to-ADAMS preprocessor. In ADAMS, it is output as an Euler angle computed as the 1st rotation in the yaw-pitch-roll rotation sequence.; About the local zt-axis
ElastoDyn['TwHt6RDxt']        = False     # (deg); Local tower angular (rotational) roll deflection (relative to the undeflected position) of tower gage 6. In ADAMS, it is output as an Euler angle computed as the 3rd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small tower deflections, so that the rotation sequence does not matter.; About the local xt-axis
ElastoDyn['TwHt6RDyt']        = False     # (deg); Local tower angular (rotational) pitch deflection (relative to the undeflected position) of tower gage 6. In ADAMS, it is output as an Euler angle computed as the 2nd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small tower deflections, so that the rotation sequence does not matter.; About the local yt-axis
ElastoDyn['TwHt6RDzt']        = False     # (deg); Local tower angular (rotational) torsion deflection (relative to the undeflected position) of tower gage 6. This output will always be zero for FAST simulation results. Use it for examining tower torsional deflections of ADAMS simulations run using ADAMS datasets created using the FAST-to-ADAMS preprocessor. In ADAMS, it is output as an Euler angle computed as the 1st rotation in the yaw-pitch-roll rotation sequence.; About the local zt-axis
ElastoDyn['TwHt7RDxt']        = False     # (deg); Local tower angular (rotational) roll deflection (relative to the undeflected position) of tower gage 7. In ADAMS, it is output as an Euler angle computed as the 3rd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small tower deflections, so that the rotation sequence does not matter.; About the local xt-axis
ElastoDyn['TwHt7RDyt']        = False     # (deg); Local tower angular (rotational) pitch deflection (relative to the undeflected position) of tower gage 7. In ADAMS, it is output as an Euler angle computed as the 2nd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small tower deflections, so that the rotation sequence does not matter.; About the local yt-axis
ElastoDyn['TwHt7RDzt']        = False     # (deg); Local tower angular (rotational) torsion deflection (relative to the undeflected position) of tower gage 7. This output will always be zero for FAST simulation results. Use it for examining tower torsional deflections of ADAMS simulations run using ADAMS datasets created using the FAST-to-ADAMS preprocessor. In ADAMS, it is output as an Euler angle computed as the 1st rotation in the yaw-pitch-roll rotation sequence.; About the local zt-axis
ElastoDyn['TwHt8RDxt']        = False     # (deg); Local tower angular (rotational) roll deflection (relative to the undeflected position) of tower gage 8. In ADAMS, it is output as an Euler angle computed as the 3rd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small tower deflections, so that the rotation sequence does not matter.; About the local xt-axis
ElastoDyn['TwHt8RDyt']        = False     # (deg); Local tower angular (rotational) pitch deflection (relative to the undeflected position) of tower gage 8. In ADAMS, it is output as an Euler angle computed as the 2nd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small tower deflections, so that the rotation sequence does not matter.; About the local yt-axis
ElastoDyn['TwHt8RDzt']        = False     # (deg); Local tower angular (rotational) torsion deflection (relative to the undeflected position) of tower gage 8. This output will always be zero for FAST simulation results. Use it for examining tower torsional deflections of ADAMS simulations run using ADAMS datasets created using the FAST-to-ADAMS preprocessor. In ADAMS, it is output as an Euler angle computed as the 1st rotation in the yaw-pitch-roll rotation sequence.; About the local zt-axis
ElastoDyn['TwHt9RDxt']        = False     # (deg); Local tower angular (rotational) roll deflection (relative to the undeflected position) of tower gage 9. In ADAMS, it is output as an Euler angle computed as the 3rd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small tower deflections, so that the rotation sequence does not matter.; About the local xt-axis
ElastoDyn['TwHt9RDyt']        = False     # (deg); Local tower angular (rotational) pitch deflection (relative to the undeflected position) of tower gage 9. In ADAMS, it is output as an Euler angle computed as the 2nd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small tower deflections, so that the rotation sequence does not matter.; About the local yt-axis
ElastoDyn['TwHt9RDzt']        = False     # (deg); Local tower angular (rotational) torsion deflection (relative to the undeflected position) of tower gage 9. This output will always be zero for FAST simulation results. Use it for examining tower torsional deflections of ADAMS simulations run using ADAMS datasets created using the FAST-to-ADAMS preprocessor. In ADAMS, it is output as an Euler angle computed as the 1st rotation in the yaw-pitch-roll rotation sequence.; About the local zt-axis
ElastoDyn['TwHt1TPxi']        = False     # (m); xi-component of the translational position (relative to the inertia frame) of tower gage 1; Directed along the local xi-axis
ElastoDyn['TwHt1TPyi']        = False     # (m); yi-component of the translational position (relative to the inertia frame) of tower gage 1; Directed along the local yi-axis
ElastoDyn['TwHt1TPzi']        = False     # (m); zi-component of the translational position (relative to ground level [onshore] or MSL [offshore]) of tower gage 1; Directed along the local zi-axis
ElastoDyn['TwHt2TPxi']        = False     # (m); xi-component of the translational position (relative to the inertia frame) of tower gage 2; Directed along the local xi-axis
ElastoDyn['TwHt2TPyi']        = False     # (m); yi-component of the translational position (relative to the inertia frame) of tower gage 2; Directed along the local yi-axis
ElastoDyn['TwHt2TPzi']        = False     # (m); zi-component of the translational position (relative to ground level [onshore] or MSL [offshore]) of tower gage 2; Directed along the local zi-axis
ElastoDyn['TwHt3TPxi']        = False     # (m); xi-component of the translational position (relative to the inertia frame) of tower gage 3; Directed along the local xi-axis
ElastoDyn['TwHt3TPyi']        = False     # (m); yi-component of the translational position (relative to the inertia frame) of tower gage 3; Directed along the local yi-axis
ElastoDyn['TwHt3TPzi']        = False     # (m); zi-component of the translational position (relative to ground level [onshore] or MSL [offshore]) of tower gage 3; Directed along the local zi-axis
ElastoDyn['TwHt4TPxi']        = False     # (m); xi-component of the translational position (relative to the inertia frame) of tower gage 4; Directed along the local xi-axis
ElastoDyn['TwHt4TPyi']        = False     # (m); yi-component of the translational position (relative to the inertia frame) of tower gage 4; Directed along the local yi-axis
ElastoDyn['TwHt4TPzi']        = False     # (m); zi-component of the translational position (relative to ground level [onshore] or MSL [offshore]) of tower gage 4; Directed along the local zi-axis
ElastoDyn['TwHt5TPxi']        = False     # (m); xi-component of the translational position (relative to the inertia frame) of tower gage 5; Directed along the local xi-axis
ElastoDyn['TwHt5TPyi']        = False     # (m); yi-component of the translational position (relative to the inertia frame) of tower gage 5; Directed along the local yi-axis
ElastoDyn['TwHt5TPzi']        = False     # (m); zi-component of the translational position (relative to ground level [onshore] or MSL [offshore]) of tower gage 5; Directed along the local zi-axis
ElastoDyn['TwHt6TPxi']        = False     # (m); xi-component of the translational position (relative to the inertia frame) of tower gage 6; Directed along the local xi-axis
ElastoDyn['TwHt6TPyi']        = False     # (m); yi-component of the translational position (relative to the inertia frame) of tower gage 6; Directed along the local yi-axis
ElastoDyn['TwHt6TPzi']        = False     # (m); zi-component of the translational position (relative to ground level [onshore] or MSL [offshore]) of tower gage 6; Directed along the local zi-axis
ElastoDyn['TwHt7TPxi']        = False     # (m); xi-component of the translational position (relative to the inertia frame) of tower gage 7; Directed along the local xi-axis
ElastoDyn['TwHt7TPyi']        = False     # (m); yi-component of the translational position (relative to the inertia frame) of tower gage 7; Directed along the local yi-axis
ElastoDyn['TwHt7TPzi']        = False     # (m); zi-component of the translational position (relative to ground level [onshore] or MSL [offshore]) of tower gage 7; Directed along the local zi-axis
ElastoDyn['TwHt8TPxi']        = False     # (m); xi-component of the translational position (relative to the inertia frame) of tower gage 8; Directed along the local xi-axis
ElastoDyn['TwHt8TPyi']        = False     # (m); yi-component of the translational position (relative to the inertia frame) of tower gage 8; Directed along the local yi-axis
ElastoDyn['TwHt8TPzi']        = False     # (m); zi-component of the translational position (relative to ground level [onshore] or MSL [offshore]) of tower gage 8; Directed along the local zi-axis
ElastoDyn['TwHt9TPxi']        = False     # (m); xi-component of the translational position (relative to the inertia frame) of tower gage 9; Directed along the local xi-axis
ElastoDyn['TwHt9TPyi']        = False     # (m); yi-component of the translational position (relative to the inertia frame) of tower gage 9; Directed along the local yi-axis
ElastoDyn['TwHt9TPzi']        = False     # (m); zi-component of the translational position (relative to ground level [onshore] or MSL [offshore]) of tower gage 9; Directed along the local zi-axis
ElastoDyn['TwHt1RPxi']        = False     # (deg); xi-component of the rotational position (relative to the inertia frame) of tower gage 1. In ADAMS, it is output as an Euler angle computed as the 3rd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small tower and platform rotational deflections, so that the rotation sequence does not matter.; About the local xi-axis
ElastoDyn['TwHt1RPyi']        = False     # (deg); yi-component of the rotational position (relative to the inertia frame) of tower gage 1. In ADAMS, it is output as an Euler angle computed as the 2nd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small tower and platform rotational deflections, so that the rotation sequence does not matter.; About the local yi-axis
ElastoDyn['TwHt1RPzi']        = False     # (deg); zi-component of the rotational position (relative to the inertia frame) of tower gage 1. In ADAMS, it is output as an Euler angle computed as the 1st rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small tower and platform rotational deflections, so that the rotation sequence does not matter.; About the local zi-axis
ElastoDyn['TwHt2RPxi']        = False     # (deg); xi-component of the rotational position (relative to the inertia frame) of tower gage 2. In ADAMS, it is output as an Euler angle computed as the 3rd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small tower and platform rotational deflections, so that the rotation sequence does not matter.; About the local xi-axis
ElastoDyn['TwHt2RPyi']        = False     # (deg); yi-component of the rotational position (relative to the inertia frame) of tower gage 2. In ADAMS, it is output as an Euler angle computed as the 2nd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small tower and platform rotational deflections, so that the rotation sequence does not matter.; About the local yi-axis
ElastoDyn['TwHt2RPzi']        = False     # (deg); zi-component of the rotational position (relative to the inertia frame) of tower gage 2. In ADAMS, it is output as an Euler angle computed as the 1st rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small tower and platform rotational deflections, so that the rotation sequence does not matter.; About the local zi-axis
ElastoDyn['TwHt3RPxi']        = False     # (deg); xi-component of the rotational position (relative to the inertia frame) of tower gage 3. In ADAMS, it is output as an Euler angle computed as the 3rd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small tower and platform rotational deflections, so that the rotation sequence does not matter.; About the local xi-axis
ElastoDyn['TwHt3RPyi']        = False     # (deg); yi-component of the rotational position (relative to the inertia frame) of tower gage 3. In ADAMS, it is output as an Euler angle computed as the 2nd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small tower and platform rotational deflections, so that the rotation sequence does not matter.; About the local yi-axis
ElastoDyn['TwHt3RPzi']        = False     # (deg); zi-component of the rotational position (relative to the inertia frame) of tower gage 3. In ADAMS, it is output as an Euler angle computed as the 1st rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small tower and platform rotational deflections, so that the rotation sequence does not matter.; About the local zi-axis
ElastoDyn['TwHt4RPxi']        = False     # (deg); xi-component of the rotational position (relative to the inertia frame) of tower gage 4. In ADAMS, it is output as an Euler angle computed as the 3rd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small tower and platform rotational deflections, so that the rotation sequence does not matter.; About the local xi-axis
ElastoDyn['TwHt4RPyi']        = False     # (deg); yi-component of the rotational position (relative to the inertia frame) of tower gage 4. In ADAMS, it is output as an Euler angle computed as the 2nd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small tower and platform rotational deflections, so that the rotation sequence does not matter.; About the local yi-axis
ElastoDyn['TwHt4RPzi']        = False     # (deg); zi-component of the rotational position (relative to the inertia frame) of tower gage 4. In ADAMS, it is output as an Euler angle computed as the 1st rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small tower and platform rotational deflections, so that the rotation sequence does not matter.; About the local zi-axis
ElastoDyn['TwHt5RPxi']        = False     # (deg); xi-component of the rotational position (relative to the inertia frame) of tower gage 5. In ADAMS, it is output as an Euler angle computed as the 3rd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small tower and platform rotational deflections, so that the rotation sequence does not matter.; About the local xi-axis
ElastoDyn['TwHt5RPyi']        = False     # (deg); yi-component of the rotational position (relative to the inertia frame) of tower gage 5. In ADAMS, it is output as an Euler angle computed as the 2nd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small tower and platform rotational deflections, so that the rotation sequence does not matter.; About the local yi-axis
ElastoDyn['TwHt5RPzi']        = False     # (deg); zi-component of the rotational position (relative to the inertia frame) of tower gage 5. In ADAMS, it is output as an Euler angle computed as the 1st rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small tower and platform rotational deflections, so that the rotation sequence does not matter.; About the local zi-axis
ElastoDyn['TwHt6RPxi']        = False     # (deg); xi-component of the rotational position (relative to the inertia frame) of tower gage 6. In ADAMS, it is output as an Euler angle computed as the 3rd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small tower and platform rotational deflections, so that the rotation sequence does not matter.; About the local xi-axis
ElastoDyn['TwHt6RPyi']        = False     # (deg); yi-component of the rotational position (relative to the inertia frame) of tower gage 6. In ADAMS, it is output as an Euler angle computed as the 2nd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small tower and platform rotational deflections, so that the rotation sequence does not matter.; About the local yi-axis
ElastoDyn['TwHt6RPzi']        = False     # (deg); zi-component of the rotational position (relative to the inertia frame) of tower gage 6. In ADAMS, it is output as an Euler angle computed as the 1st rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small tower and platform rotational deflections, so that the rotation sequence does not matter.; About the local zi-axis
ElastoDyn['TwHt7RPxi']        = False     # (deg); xi-component of the rotational position (relative to the inertia frame) of tower gage 7. In ADAMS, it is output as an Euler angle computed as the 3rd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small tower and platform rotational deflections, so that the rotation sequence does not matter.; About the local xi-axis
ElastoDyn['TwHt7RPyi']        = False     # (deg); yi-component of the rotational position (relative to the inertia frame) of tower gage 7. In ADAMS, it is output as an Euler angle computed as the 2nd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small tower and platform rotational deflections, so that the rotation sequence does not matter.; About the local yi-axis
ElastoDyn['TwHt7RPzi']        = False     # (deg); zi-component of the rotational position (relative to the inertia frame) of tower gage 7. In ADAMS, it is output as an Euler angle computed as the 1st rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small tower and platform rotational deflections, so that the rotation sequence does not matter.; About the local zi-axis
ElastoDyn['TwHt8RPxi']        = False     # (deg); xi-component of the rotational position (relative to the inertia frame) of tower gage 8. In ADAMS, it is output as an Euler angle computed as the 3rd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small tower and platform rotational deflections, so that the rotation sequence does not matter.; About the local xi-axis
ElastoDyn['TwHt8RPyi']        = False     # (deg); yi-component of the rotational position (relative to the inertia frame) of tower gage 8. In ADAMS, it is output as an Euler angle computed as the 2nd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small tower and platform rotational deflections, so that the rotation sequence does not matter.; About the local yi-axis
ElastoDyn['TwHt8RPzi']        = False     # (deg); zi-component of the rotational position (relative to the inertia frame) of tower gage 8. In ADAMS, it is output as an Euler angle computed as the 1st rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small tower and platform rotational deflections, so that the rotation sequence does not matter.; About the local zi-axis
ElastoDyn['TwHt9RPxi']        = False     # (deg); xi-component of the rotational position (relative to the inertia frame) of tower gage 9. In ADAMS, it is output as an Euler angle computed as the 3rd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small tower and platform rotational deflections, so that the rotation sequence does not matter.; About the local xi-axis
ElastoDyn['TwHt9RPyi']        = False     # (deg); yi-component of the rotational position (relative to the inertia frame) of tower gage 9. In ADAMS, it is output as an Euler angle computed as the 2nd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small tower and platform rotational deflections, so that the rotation sequence does not matter.; About the local yi-axis
ElastoDyn['TwHt9RPzi']        = False     # (deg); zi-component of the rotational position (relative to the inertia frame) of tower gage 9. In ADAMS, it is output as an Euler angle computed as the 1st rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small tower and platform rotational deflections, so that the rotation sequence does not matter.; About the local zi-axis

# Platform Motions
ElastoDyn['PtfmTDxt']         = False     # (m); Platform horizontal surge (translational) displacement; Directed along the xt-axis
ElastoDyn['PtfmTDyt']         = False     # (m); Platform horizontal sway (translational) displacement; Directed along the yt-axis
ElastoDyn['PtfmTDzt']         = False     # (m); Platform vertical heave (translational) displacement; Directed along the zt-axis
ElastoDyn['PtfmTDxi']         = False     # (m); Platform horizontal surge (translational) displacement; Directed along the xi-axis
ElastoDyn['PtfmSurge']        = False     # (m); Platform horizontal surge (translational) displacement; Directed along the xi-axis
ElastoDyn['PtfmTDyi']         = False     # (m); Platform horizontal sway (translational) displacement; Directed along the yi-axis
ElastoDyn['PtfmSway']         = False     # (m); Platform horizontal sway (translational) displacement; Directed along the yi-axis
ElastoDyn['PtfmTDzi']         = False     # (m); Platform vertical heave (translational) displacement; Directed along the zi-axis
ElastoDyn['PtfmHeave']        = False     # (m); Platform vertical heave (translational) displacement; Directed along the zi-axis
ElastoDyn['PtfmTVxt']         = False     # (m/s); Platform horizontal surge (translational) velocity; Directed along the xt-axis
ElastoDyn['PtfmTVyt']         = False     # (m/s); Platform horizontal sway (translational) velocity; Directed along the yt-axis
ElastoDyn['PtfmTVzt']         = False     # (m/s); Platform vertical heave (translational) velocity; Directed along the zt-axis
ElastoDyn['PtfmTVxi']         = False     # (m/s); Platform horizontal surge (translational) velocity; Directed along the xi-axis
ElastoDyn['PtfmTVyi']         = False     # (m/s); Platform horizontal sway (translational) velocity; Directed along the yi-axis
ElastoDyn['PtfmTVzi']         = False     # (m/s); Platform vertical heave (translational) velocity; Directed along the zi-axis
ElastoDyn['PtfmTAxt']         = False     # (m/s^2); Platform horizontal surge (translational) acceleration; Directed along the xt-axis
ElastoDyn['PtfmTAyt']         = False     # (m/s^2); Platform horizontal sway (translational) acceleration; Directed along the yt-axis
ElastoDyn['PtfmTAzt']         = False     # (m/s^2); Platform vertical heave (translational) acceleration; Directed along the zt-axis
ElastoDyn['PtfmTAgxt']        = False     # (m/s^2); Platform horizontal surge (translational) acceleration relative to g; Directed along the xt-axis
ElastoDyn['PtfmTAgyt']        = False     # (m/s^2); Platform horizontal sway (translational) acceleration relative to g; Directed along the yt-axis
ElastoDyn['PtfmTAgzt']        = False     # (m/s^2); Platform vertical heave (translational) acceleration relative to g; Directed along the zt-axis
ElastoDyn['PtfmTAxi']         = False     # (m/s^2); Platform horizontal surge (translational) acceleration; Directed along the xi-axis
ElastoDyn['PtfmTAyi']         = False     # (m/s^2); Platform horizontal sway (translational) acceleration; Directed along the yi-axis
ElastoDyn['PtfmTAzi']         = False     # (m/s^2); Platform vertical heave (translational) acceleration; Directed along the zi-axis
ElastoDyn['PtfmTAgxi']        = False     # (m/s^2); Platform horizontal surge (translational) acceleration relative to g; Directed along the xi-axis
ElastoDyn['PtfmTAgyi']        = False     # (m/s^2); Platform horizontal sway (translational) acceleration relative to g; Directed along the yi-axis
ElastoDyn['PtfmTAgzi']        = False     # (m/s^2); Platform vertical heave (translational) acceleration relative to g; Directed along the zi-axis
ElastoDyn['PtfmRDxi']         = False     # (deg); Platform roll tilt angular (rotational) displacement. In ADAMS, it is output as an Euler angle computed as the 3rd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small rotational platform displacements, so that the rotation sequence does not matter.; About the xi-axis
ElastoDyn['PtfmRoll']         = False     # (deg); Platform roll tilt angular (rotational) displacement. In ADAMS, it is output as an Euler angle computed as the 3rd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small rotational platform displacements, so that the rotation sequence does not matter.; About the xi-axis
ElastoDyn['PtfmRDyi']         = False     # (deg); Platform pitch tilt angular (rotational) displacement. In ADAMS, it is output as an Euler angle computed as the 2nd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small rotational platform displacements, so that the rotation sequence does not matter.; About the yi-axis
ElastoDyn['PtfmPitch']        = False     # (deg); Platform pitch tilt angular (rotational) displacement. In ADAMS, it is output as an Euler angle computed as the 2nd rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small rotational platform displacements, so that the rotation sequence does not matter.; About the yi-axis
ElastoDyn['PtfmRDzi']         = False     # (deg); Platform yaw angular (rotational) displacement. In ADAMS, it is output as an Euler angle computed as the 1st rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small rotational platform displacements, so that the rotation sequence does not matter.; About the zi-axis
ElastoDyn['PtfmYaw']          = False     # (deg); Platform yaw angular (rotational) displacement. In ADAMS, it is output as an Euler angle computed as the 1st rotation in the yaw-pitch-roll rotation sequence. It is not output as an Euler angle in FAST, which assumes small rotational platform displacements, so that the rotation sequence does not matter.; About the zi-axis
ElastoDyn['PtfmRVxt']         = False     # (deg/s); Platform roll tilt angular (rotational) velocity; About the xt-axis
ElastoDyn['PtfmRVyt']         = False     # (deg/s); Platform pitch tilt angular (rotational) velocity; About the yt-axis
ElastoDyn['PtfmRVzt']         = False     # (deg/s); Platform yaw angular (rotational) velocity; About the zt-axis
ElastoDyn['PtfmRVxi']         = False     # (deg/s); Platform roll tilt angular (rotational) velocity; About the xi-axis
ElastoDyn['PtfmRVyi']         = False     # (deg/s); Platform pitch tilt angular (rotational) velocity; About the yi-axis
ElastoDyn['PtfmRVzi']         = False     # (deg/s); Platform yaw angular (rotational) velocity; About the zi-axis
ElastoDyn['PtfmRAxt']         = False     # (deg/s^2); Platform roll tilt angular (rotational) acceleration; About the xt-axis
ElastoDyn['PtfmRAyt']         = False     # (deg/s^2); Platform pitch tilt angular (rotational) acceleration; About the yt-axis
ElastoDyn['PtfmRAzt']         = False     # (deg/s^2); Platform yaw angular (rotational) acceleration; About the zt-axis
ElastoDyn['PtfmRAxi']         = False     # (deg/s^2); Platform roll tilt angular (rotational) acceleration; About the xi-axis
ElastoDyn['PtfmRAyi']         = False     # (deg/s^2); Platform pitch tilt angular (rotational) acceleration; About the yi-axis
ElastoDyn['PtfmRAzi']         = False     # (deg/s^2); Platform yaw angular (rotational) acceleration; About the zi-axis

# Blade 1 Root Loads
ElastoDyn['RootFxc1']         = False     # (kN); Blade 1 out-of-plane shear force at the blade root; Directed along the xc1-axis
ElastoDyn['RootFyc1']         = False     # (kN); Blade 1 in-plane shear force at the blade root; Directed along the yc1-axis
ElastoDyn['RootFzc1']         = False     # (kN); Blade 1 axial force at the blade root; Directed along the zc1- and zb1-axes
ElastoDyn['RootFzb1']         = False     # (kN); Blade 1 axial force at the blade root; Directed along the zc1- and zb1-axes
ElastoDyn['RootFxb1']         = False     # (kN); Blade 1 flapwise shear force at the blade root; Directed along the xb1-axis
ElastoDyn['RootFyb1']         = False     # (kN); Blade 1 edgewise shear force at the blade root; Directed along the yb1-axis
ElastoDyn['RootMxc1']         = False     # (kN-m); Blade 1 in-plane moment (i.e., the moment caused by in-plane forces) at the blade root; About the xc1-axis
ElastoDyn['RootMIP1']         = False     # (kN-m); Blade 1 in-plane moment (i.e., the moment caused by in-plane forces) at the blade root; About the xc1-axis
ElastoDyn['RootMyc1']         = False     # (kN-m); Blade 1 out-of-plane moment (i.e., the moment caused by out-of-plane forces) at the blade root; About the yc1-axis
ElastoDyn['RootMOoP1']        = False     # (kN-m); Blade 1 out-of-plane moment (i.e., the moment caused by out-of-plane forces) at the blade root; About the yc1-axis
ElastoDyn['RootMzc1']         = False     # (kN-m); Blade 1 pitching moment at the blade root; About the zc1- and zb1-axes
ElastoDyn['RootMzb1']         = False     # (kN-m); Blade 1 pitching moment at the blade root; About the zc1- and zb1-axes
ElastoDyn['RootMxb1']         = False     # (kN-m); Blade 1 edgewise moment (i.e., the moment caused by edgewise forces) at the blade root; About the xb1-axis
ElastoDyn['RootMEdg1']        = False     # (kN-m); Blade 1 edgewise moment (i.e., the moment caused by edgewise forces) at the blade root; About the xb1-axis
ElastoDyn['RootMyb1']         = True      # (kN-m); Blade 1 flapwise moment (i.e., the moment caused by flapwise forces) at the blade root; About the yb1-axis
ElastoDyn['RootMFlp1']        = False     # (kN-m); Blade 1 flapwise moment (i.e., the moment caused by flapwise forces) at the blade root; About the yb1-axis

# Blade 2 Root Loads
ElastoDyn['RootFxc2']         = False     # (kN); Blade 2 out-of-plane shear force at the blade root; Directed along the xc2-axis
ElastoDyn['RootFyc2']         = False     # (kN); Blade 2 in-plane shear force at the blade root; Directed along the yc2-axis
ElastoDyn['RootFzc2']         = False     # (kN); Blade 2 axial force at the blade root; Directed along the zc2- and zb2-axes
ElastoDyn['RootFzb2']         = False     # (kN); Blade 2 axial force at the blade root; Directed along the zc2- and zb2-axes
ElastoDyn['RootFxb2']         = False     # (kN); Blade 2 flapwise shear force at the blade root; Directed along the xb2-axis
ElastoDyn['RootFyb2']         = False     # (kN); Blade 2 edgewise shear force at the blade root; Directed along the yb2-axis
ElastoDyn['RootMxc2']         = False     # (kN-m); Blade 2 in-plane moment (i.e., the moment caused by in-plane forces) at the blade root; About the xc2-axis
ElastoDyn['RootMIP2']         = False     # (kN-m); Blade 2 in-plane moment (i.e., the moment caused by in-plane forces) at the blade root; About the xc2-axis
ElastoDyn['RootMyc2']         = False     # (kN-m); Blade 2 out-of-plane moment (i.e., the moment caused by out-of-plane forces) at the blade root; About the yc2-axis
ElastoDyn['RootMOoP2']        = False     # (kN-m); Blade 2 out-of-plane moment (i.e., the moment caused by out-of-plane forces) at the blade root; About the yc2-axis
ElastoDyn['RootMzc2']         = False     # (kN-m); Blade 2 pitching moment at the blade root; About the zc2- and zb2-axes
ElastoDyn['RootMzb2']         = False     # (kN-m); Blade 2 pitching moment at the blade root; About the zc2- and zb2-axes
ElastoDyn['RootMxb2']         = False     # (kN-m); Blade 2 edgewise moment (i.e., the moment caused by edgewise forces) at the blade root; About the xb2-axis
ElastoDyn['RootMEdg2']        = False     # (kN-m); Blade 2 edgewise moment (i.e., the moment caused by edgewise forces) at the blade root; About the xb2-axis
ElastoDyn['RootMyb2']         = True      # (kN-m); Blade 2 flapwise moment (i.e., the moment caused by flapwise forces) at the blade root; About the yb2-axis
ElastoDyn['RootMFlp2']        = False     # (kN-m); Blade 2 flapwise moment (i.e., the moment caused by flapwise forces) at the blade root; About the yb2-axis

# Blade 3 Root Loads
ElastoDyn['RootFxc3']         = False     # (kN); Blade 3 out-of-plane shear force at the blade root; Directed along the xc3-axis
ElastoDyn['RootFyc3']         = False     # (kN); Blade 3 in-plane shear force at the blade root; Directed along the yc3-axis
ElastoDyn['RootFzc3']         = False     # (kN); Blade 3 axial force at the blade root; Directed along the zc3- and zb3-axes
ElastoDyn['RootFzb3']         = False     # (kN); Blade 3 axial force at the blade root; Directed along the zc3- and zb3-axes
ElastoDyn['RootFxb3']         = False     # (kN); Blade 3 flapwise shear force at the blade root; Directed along the xb3-axis
ElastoDyn['RootFyb3']         = False     # (kN); Blade 3 edgewise shear force at the blade root; Directed along the yb3-axis
ElastoDyn['RootMxc3']         = False     # (kN-m); Blade 3 in-plane moment (i.e., the moment caused by in-plane forces) at the blade root; About the xc3-axis
ElastoDyn['RootMIP3']         = False     # (kN-m); Blade 3 in-plane moment (i.e., the moment caused by in-plane forces) at the blade root; About the xc3-axis
ElastoDyn['RootMyc3']         = False     # (kN-m); Blade 3 out-of-plane moment (i.e., the moment caused by out-of-plane forces) at the blade root; About the yc3-axis
ElastoDyn['RootMOoP3']        = False     # (kN-m); Blade 3 out-of-plane moment (i.e., the moment caused by out-of-plane forces) at the blade root; About the yc3-axis
ElastoDyn['RootMzc3']         = False     # (kN-m); Blade 3 pitching moment at the blade root; About the zc3- and zb3-axes
ElastoDyn['RootMzb3']         = False     # (kN-m); Blade 3 pitching moment at the blade root; About the zc3- and zb3-axes
ElastoDyn['RootMxb3']         = False     # (kN-m); Blade 3 edgewise moment (i.e., the moment caused by edgewise forces) at the blade root; About the xb3-axis
ElastoDyn['RootMEdg3']        = False     # (kN-m); Blade 3 edgewise moment (i.e., the moment caused by edgewise forces) at the blade root; About the xb3-axis
ElastoDyn['RootMyb3']         = True      # (kN-m); Blade 3 flapwise moment (i.e., the moment caused by flapwise forces) at the blade root; About the yb3-axis
ElastoDyn['RootMFlp3']        = False     # (kN-m); Blade 3 flapwise moment (i.e., the moment caused by flapwise forces) at the blade root; About the yb3-axis

# Blade 1 Local Span Loads
ElastoDyn['Spn1MLxb1']        = False     # (kN-m); Blade 1 local edgewise moment at span station 1; About the local xb1-axis
ElastoDyn['Spn1MLyb1']        = False     # (kN-m); Blade 1 local flapwise moment at span station 1; About the local yb1-axis
ElastoDyn['Spn1MLzb1']        = False     # (kN-m); Blade 1 local pitching moment at span station 1; About the local zb1-axis
ElastoDyn['Spn2MLxb1']        = False     # (kN-m); Blade 1 local edgewise moment at span station 2; About the local xb1-axis
ElastoDyn['Spn2MLyb1']        = False     # (kN-m); Blade 1 local flapwise moment at span station 2; About the local yb1-axis
ElastoDyn['Spn2MLzb1']        = False     # (kN-m); Blade 1 local pitching moment at span station 2; About the local zb1-axis
ElastoDyn['Spn3MLxb1']        = False     # (kN-m); Blade 1 local edgewise moment at span station 3; About the local xb1-axis
ElastoDyn['Spn3MLyb1']        = False     # (kN-m); Blade 1 local flapwise moment at span station 3; About the local yb1-axis
ElastoDyn['Spn3MLzb1']        = False     # (kN-m); Blade 1 local pitching moment at span station 3; About the local zb1-axis
ElastoDyn['Spn4MLxb1']        = False     # (kN-m); Blade 1 local edgewise moment at span station 4; About the local xb1-axis
ElastoDyn['Spn4MLyb1']        = False     # (kN-m); Blade 1 local flapwise moment at span station 4; About the local yb1-axis
ElastoDyn['Spn4MLzb1']        = False     # (kN-m); Blade 1 local pitching moment at span station 4; About the local zb1-axis
ElastoDyn['Spn5MLxb1']        = False     # (kN-m); Blade 1 local edgewise moment at span station 5; About the local xb1-axis
ElastoDyn['Spn5MLyb1']        = False     # (kN-m); Blade 1 local flapwise moment at span station 5; About the local yb1-axis
ElastoDyn['Spn5MLzb1']        = False     # (kN-m); Blade 1 local pitching moment at span station 5; About the local zb1-axis
ElastoDyn['Spn6MLxb1']        = False     # (kN-m); Blade 1 local edgewise moment at span station 6; About the local xb1-axis
ElastoDyn['Spn6MLyb1']        = False     # (kN-m); Blade 1 local flapwise moment at span station 6; About the local yb1-axis
ElastoDyn['Spn6MLzb1']        = False     # (kN-m); Blade 1 local pitching moment at span station 6; About the local zb1-axis
ElastoDyn['Spn7MLxb1']        = False     # (kN-m); Blade 1 local edgewise moment at span station 7; About the local xb1-axis
ElastoDyn['Spn7MLyb1']        = False     # (kN-m); Blade 1 local flapwise moment at span station 7; About the local yb1-axis
ElastoDyn['Spn7MLzb1']        = False     # (kN-m); Blade 1 local pitching moment at span station 7; About the local zb1-axis
ElastoDyn['Spn8MLxb1']        = False     # (kN-m); Blade 1 local edgewise moment at span station 8; About the local xb1-axis
ElastoDyn['Spn8MLyb1']        = False     # (kN-m); Blade 1 local flapwise moment at span station 8; About the local yb1-axis
ElastoDyn['Spn8MLzb1']        = False     # (kN-m); Blade 1 local pitching moment at span station 8; About the local zb1-axis
ElastoDyn['Spn9MLxb1']        = False     # (kN-m); Blade 1 local edgewise moment at span station 9; About the local xb1-axis
ElastoDyn['Spn9MLyb1']        = False     # (kN-m); Blade 1 local flapwise moment at span station 9; About the local yb1-axis
ElastoDyn['Spn9MLzb1']        = False     # (kN-m); Blade 1 local pitching moment at span station 9; About the local zb1-axis
ElastoDyn['Spn1FLxb1']        = False     # (kN); Blade 1 local flapwise shear force at span station 1; Directed along the local xb1-axis
ElastoDyn['Spn1FLyb1']        = False     # (kN); Blade 1 local edgewise shear force at span station 1; Directed along the local yb1-axis
ElastoDyn['Spn1FLzb1']        = False     # (kN); Blade 1 local axial force at span station 1; Directed along the local zb1-axis
ElastoDyn['Spn2FLxb1']        = False     # (kN); Blade 1 local flapwise shear force at span station 2; Directed along the local xb1-axis
ElastoDyn['Spn2FLyb1']        = False     # (kN); Blade 1 local edgewise shear force at span station 2; Directed along the local yb1-axis
ElastoDyn['Spn2FLzb1']        = False     # (kN); Blade 1 local axial force at span station 2; Directed along the local zb1-axis
ElastoDyn['Spn3FLxb1']        = False     # (kN); Blade 1 local flapwise shear force at span station 3; Directed along the local xb1-axis
ElastoDyn['Spn3FLyb1']        = False     # (kN); Blade 1 local edgewise shear force at span station 3; Directed along the local yb1-axis
ElastoDyn['Spn3FLzb1']        = False     # (kN); Blade 1 local axial force at span station 3; Directed along the local zb1-axis
ElastoDyn['Spn4FLxb1']        = False     # (kN); Blade 1 local flapwise shear force at span station 4; Directed along the local xb1-axis
ElastoDyn['Spn4FLyb1']        = False     # (kN); Blade 1 local edgewise shear force at span station 4; Directed along the local yb1-axis
ElastoDyn['Spn4FLzb1']        = False     # (kN); Blade 1 local axial force at span station 4; Directed along the local zb1-axis
ElastoDyn['Spn5FLxb1']        = False     # (kN); Blade 1 local flapwise shear force at span station 5; Directed along the local xb1-axis
ElastoDyn['Spn5FLyb1']        = False     # (kN); Blade 1 local edgewise shear force at span station 5; Directed along the local yb1-axis
ElastoDyn['Spn5FLzb1']        = False     # (kN); Blade 1 local axial force at span station 5; Directed along the local zb1-axis
ElastoDyn['Spn6FLxb1']        = False     # (kN); Blade 1 local flapwise shear force at span station 6; Directed along the local xb1-axis
ElastoDyn['Spn6FLyb1']        = False     # (kN); Blade 1 local edgewise shear force at span station 6; Directed along the local yb1-axis
ElastoDyn['Spn6FLzb1']        = False     # (kN); Blade 1 local axial force at span station 6; Directed along the local zb1-axis
ElastoDyn['Spn7FLxb1']        = False     # (kN); Blade 1 local flapwise shear force at span station 7; Directed along the local xb1-axis
ElastoDyn['Spn7FLyb1']        = False     # (kN); Blade 1 local edgewise shear force at span station 7; Directed along the local yb1-axis
ElastoDyn['Spn7FLzb1']        = False     # (kN); Blade 1 local axial force at span station 7; Directed along the local zb1-axis
ElastoDyn['Spn8FLxb1']        = False     # (kN); Blade 1 local flapwise shear force at span station 8; Directed along the local xb1-axis
ElastoDyn['Spn8FLyb1']        = False     # (kN); Blade 1 local edgewise shear force at span station 8; Directed along the local yb1-axis
ElastoDyn['Spn8FLzb1']        = False     # (kN); Blade 1 local axial force at span station 8; Directed along the local zb1-axis
ElastoDyn['Spn9FLxb1']        = False     # (kN); Blade 1 local flapwise shear force at span station 9; Directed along the local xb1-axis
ElastoDyn['Spn9FLyb1']        = False     # (kN); Blade 1 local edgewise shear force at span station 9; Directed along the local yb1-axis
ElastoDyn['Spn9FLzb1']        = False     # (kN); Blade 1 local axial force at span station 9; Directed along the local zb1-axis

# Blade 2 Local Span Loads
ElastoDyn['Spn1MLxb2']        = False     # (kN-m); Blade 2 local edgewise moment at span station 1; About the local xb2-axis
ElastoDyn['Spn1MLyb2']        = False     # (kN-m); Blade 2 local flapwise moment at span station 1; About the local yb2-axis
ElastoDyn['Spn1MLzb2']        = False     # (kN-m); Blade 2 local pitching moment at span station 1; About the local zb2-axis
ElastoDyn['Spn2MLxb2']        = False     # (kN-m); Blade 2 local edgewise moment at span station 2; About the local xb2-axis
ElastoDyn['Spn2MLyb2']        = False     # (kN-m); Blade 2 local flapwise moment at span station 2; About the local yb2-axis
ElastoDyn['Spn2MLzb2']        = False     # (kN-m); Blade 2 local pitching moment at span station 2; About the local zb2-axis
ElastoDyn['Spn3MLxb2']        = False     # (kN-m); Blade 2 local edgewise moment at span station 3; About the local xb2-axis
ElastoDyn['Spn3MLyb2']        = False     # (kN-m); Blade 2 local flapwise moment at span station 3; About the local yb2-axis
ElastoDyn['Spn3MLzb2']        = False     # (kN-m); Blade 2 local pitching moment at span station 3; About the local zb2-axis
ElastoDyn['Spn4MLxb2']        = False     # (kN-m); Blade 2 local edgewise moment at span station 4; About the local xb2-axis
ElastoDyn['Spn4MLyb2']        = False     # (kN-m); Blade 2 local flapwise moment at span station 4; About the local yb2-axis
ElastoDyn['Spn4MLzb2']        = False     # (kN-m); Blade 2 local pitching moment at span station 4; About the local zb2-axis
ElastoDyn['Spn5MLxb2']        = False     # (kN-m); Blade 2 local edgewise moment at span station 5; About the local xb2-axis
ElastoDyn['Spn5MLyb2']        = False     # (kN-m); Blade 2 local flapwise moment at span station 5; About the local yb2-axis
ElastoDyn['Spn5MLzb2']        = False     # (kN-m); Blade 2 local pitching moment at span station 5; About the local zb2-axis
ElastoDyn['Spn6MLxb2']        = False     # (kN-m); Blade 2 local edgewise moment at span station 6; About the local xb2-axis
ElastoDyn['Spn6MLyb2']        = False     # (kN-m); Blade 2 local flapwise moment at span station 6; About the local yb2-axis
ElastoDyn['Spn6MLzb2']        = False     # (kN-m); Blade 2 local pitching moment at span station 6; About the local zb2-axis
ElastoDyn['Spn7MLxb2']        = False     # (kN-m); Blade 2 local edgewise moment at span station 7; About the local xb2-axis
ElastoDyn['Spn7MLyb2']        = False     # (kN-m); Blade 2 local flapwise moment at span station 7; About the local yb2-axis
ElastoDyn['Spn7MLzb2']        = False     # (kN-m); Blade 2 local pitching moment at span station 7; About the local zb2-axis
ElastoDyn['Spn8MLxb2']        = False     # (kN-m); Blade 2 local edgewise moment at span station 8; About the local xb2-axis
ElastoDyn['Spn8MLyb2']        = False     # (kN-m); Blade 2 local flapwise moment at span station 8; About the local yb2-axis
ElastoDyn['Spn8MLzb2']        = False     # (kN-m); Blade 2 local pitching moment at span station 8; About the local zb2-axis
ElastoDyn['Spn9MLxb2']        = False     # (kN-m); Blade 2 local edgewise moment at span station 9; About the local xb2-axis
ElastoDyn['Spn9MLyb2']        = False     # (kN-m); Blade 2 local flapwise moment at span station 9; About the local yb2-axis
ElastoDyn['Spn9MLzb2']        = False     # (kN-m); Blade 2 local pitching moment at span station 9; About the local zb2-axis
ElastoDyn['Spn1FLxb2']        = False     # (kN); Blade 2 local flapwise shear force at span station 1; Directed along the local xb2-axis
ElastoDyn['Spn1FLyb2']        = False     # (kN); Blade 2 local edgewise shear force at span station 1; Directed along the local yb2-axis
ElastoDyn['Spn1FLzb2']        = False     # (kN); Blade 2 local axial force at span station 1; Directed along the local zb2-axis
ElastoDyn['Spn2FLxb2']        = False     # (kN); Blade 2 local flapwise shear force at span station 2; Directed along the local xb2-axis
ElastoDyn['Spn2FLyb2']        = False     # (kN); Blade 2 local edgewise shear force at span station 2; Directed along the local yb2-axis
ElastoDyn['Spn2FLzb2']        = False     # (kN); Blade 2 local axial force at span station 2; Directed along the local zb2-axis
ElastoDyn['Spn3FLxb2']        = False     # (kN); Blade 2 local flapwise shear force at span station 3; Directed along the local xb2-axis
ElastoDyn['Spn3FLyb2']        = False     # (kN); Blade 2 local edgewise shear force at span station 3; Directed along the local yb2-axis
ElastoDyn['Spn3FLzb2']        = False     # (kN); Blade 2 local axial force at span station 3; Directed along the local zb2-axis
ElastoDyn['Spn4FLxb2']        = False     # (kN); Blade 2 local flapwise shear force at span station 4; Directed along the local xb2-axis
ElastoDyn['Spn4FLyb2']        = False     # (kN); Blade 2 local edgewise shear force at span station 4; Directed along the local yb2-axis
ElastoDyn['Spn4FLzb2']        = False     # (kN); Blade 2 local axial force at span station 4; Directed along the local zb2-axis
ElastoDyn['Spn5FLxb2']        = False     # (kN); Blade 2 local flapwise shear force at span station 5; Directed along the local xb2-axis
ElastoDyn['Spn5FLyb2']        = False     # (kN); Blade 2 local edgewise shear force at span station 5; Directed along the local yb2-axis
ElastoDyn['Spn5FLzb2']        = False     # (kN); Blade 2 local axial force at span station 5; Directed along the local zb2-axis
ElastoDyn['Spn6FLxb2']        = False     # (kN); Blade 2 local flapwise shear force at span station 6; Directed along the local xb2-axis
ElastoDyn['Spn6FLyb2']        = False     # (kN); Blade 2 local edgewise shear force at span station 6; Directed along the local yb2-axis
ElastoDyn['Spn6FLzb2']        = False     # (kN); Blade 2 local axial force at span station 6; Directed along the local zb2-axis
ElastoDyn['Spn7FLxb2']        = False     # (kN); Blade 2 local flapwise shear force at span station 7; Directed along the local xb2-axis
ElastoDyn['Spn7FLyb2']        = False     # (kN); Blade 2 local edgewise shear force at span station 7; Directed along the local yb2-axis
ElastoDyn['Spn7FLzb2']        = False     # (kN); Blade 2 local axial force at span station 7; Directed along the local zb2-axis
ElastoDyn['Spn8FLxb2']        = False     # (kN); Blade 2 local flapwise shear force at span station 8; Directed along the local xb2-axis
ElastoDyn['Spn8FLyb2']        = False     # (kN); Blade 2 local edgewise shear force at span station 8; Directed along the local yb2-axis
ElastoDyn['Spn8FLzb2']        = False     # (kN); Blade 2 local axial force at span station 8; Directed along the local zb2-axis
ElastoDyn['Spn9FLxb2']        = False     # (kN); Blade 2 local flapwise shear force at span station 9; Directed along the local xb2-axis
ElastoDyn['Spn9FLyb2']        = False     # (kN); Blade 2 local edgewise shear force at span station 9; Directed along the local yb2-axis
ElastoDyn['Spn9FLzb2']        = False     # (kN); Blade 2 local axial force at span station 9; Directed along the local zb2-axis

# Blade 3 Local Span Loads
ElastoDyn['Spn1MLxb3']        = False     # (kN-m); Blade 3 local edgewise moment at span station 1; About the local xb3-axis
ElastoDyn['Spn1MLyb3']        = False     # (kN-m); Blade 3 local flapwise moment at span station 1; About the local yb3-axis
ElastoDyn['Spn1MLzb3']        = False     # (kN-m); Blade 3 local pitching moment at span station 1; About the local zb3-axis
ElastoDyn['Spn2MLxb3']        = False     # (kN-m); Blade 3 local edgewise moment at span station 2; About the local xb3-axis
ElastoDyn['Spn2MLyb3']        = False     # (kN-m); Blade 3 local flapwise moment at span station 2; About the local yb3-axis
ElastoDyn['Spn2MLzb3']        = False     # (kN-m); Blade 3 local pitching moment at span station 2; About the local zb3-axis
ElastoDyn['Spn3MLxb3']        = False     # (kN-m); Blade 3 local edgewise moment at span station 3; About the local xb3-axis
ElastoDyn['Spn3MLyb3']        = False     # (kN-m); Blade 3 local flapwise moment at span station 3; About the local yb3-axis
ElastoDyn['Spn3MLzb3']        = False     # (kN-m); Blade 3 local pitching moment at span station 3; About the local zb3-axis
ElastoDyn['Spn4MLxb3']        = False     # (kN-m); Blade 3 local edgewise moment at span station 4; About the local xb3-axis
ElastoDyn['Spn4MLyb3']        = False     # (kN-m); Blade 3 local flapwise moment at span station 4; About the local yb3-axis
ElastoDyn['Spn4MLzb3']        = False     # (kN-m); Blade 3 local pitching moment at span station 4; About the local zb3-axis
ElastoDyn['Spn5MLxb3']        = False     # (kN-m); Blade 3 local edgewise moment at span station 5; About the local xb3-axis
ElastoDyn['Spn5MLyb3']        = False     # (kN-m); Blade 3 local flapwise moment at span station 5; About the local yb3-axis
ElastoDyn['Spn5MLzb3']        = False     # (kN-m); Blade 3 local pitching moment at span station 5; About the local zb3-axis
ElastoDyn['Spn6MLxb3']        = False     # (kN-m); Blade 3 local edgewise moment at span station 6; About the local xb3-axis
ElastoDyn['Spn6MLyb3']        = False     # (kN-m); Blade 3 local flapwise moment at span station 6; About the local yb3-axis
ElastoDyn['Spn6MLzb3']        = False     # (kN-m); Blade 3 local pitching moment at span station 6; About the local zb3-axis
ElastoDyn['Spn7MLxb3']        = False     # (kN-m); Blade 3 local edgewise moment at span station 7; About the local xb3-axis
ElastoDyn['Spn7MLyb3']        = False     # (kN-m); Blade 3 local flapwise moment at span station 7; About the local yb3-axis
ElastoDyn['Spn7MLzb3']        = False     # (kN-m); Blade 3 local pitching moment at span station 7; About the local zb3-axis
ElastoDyn['Spn8MLxb3']        = False     # (kN-m); Blade 3 local edgewise moment at span station 8; About the local xb3-axis
ElastoDyn['Spn8MLyb3']        = False     # (kN-m); Blade 3 local flapwise moment at span station 8; About the local yb3-axis
ElastoDyn['Spn8MLzb3']        = False     # (kN-m); Blade 3 local pitching moment at span station 8; About the local zb3-axis
ElastoDyn['Spn9MLxb3']        = False     # (kN-m); Blade 3 local edgewise moment at span station 9; About the local xb3-axis
ElastoDyn['Spn9MLyb3']        = False     # (kN-m); Blade 3 local flapwise moment at span station 9; About the local yb3-axis
ElastoDyn['Spn9MLzb3']        = False     # (kN-m); Blade 3 local pitching moment at span station 9; About the local zb3-axis
ElastoDyn['Spn1FLxb3']        = False     # (kN); Blade 3 local flapwise shear force at span station 1; Directed along the local xb3-axis
ElastoDyn['Spn1FLyb3']        = False     # (kN); Blade 3 local edgewise shear force at span station 1; Directed along the local yb3-axis
ElastoDyn['Spn1FLzb3']        = False     # (kN); Blade 3 local axial force at span station 1; Directed along the local zb3-axis
ElastoDyn['Spn2FLxb3']        = False     # (kN); Blade 3 local flapwise shear force at span station 2; Directed along the local xb3-axis
ElastoDyn['Spn2FLyb3']        = False     # (kN); Blade 3 local edgewise shear force at span station 2; Directed along the local yb3-axis
ElastoDyn['Spn2FLzb3']        = False     # (kN); Blade 3 local axial force at span station 2; Directed along the local zb3-axis
ElastoDyn['Spn3FLxb3']        = False     # (kN); Blade 3 local flapwise shear force at span station 3; Directed along the local xb3-axis
ElastoDyn['Spn3FLyb3']        = False     # (kN); Blade 3 local edgewise shear force at span station 3; Directed along the local yb3-axis
ElastoDyn['Spn3FLzb3']        = False     # (kN); Blade 3 local axial force at span station 3; Directed along the local zb3-axis
ElastoDyn['Spn4FLxb3']        = False     # (kN); Blade 3 local flapwise shear force at span station 4; Directed along the local xb3-axis
ElastoDyn['Spn4FLyb3']        = False     # (kN); Blade 3 local edgewise shear force at span station 4; Directed along the local yb3-axis
ElastoDyn['Spn4FLzb3']        = False     # (kN); Blade 3 local axial force at span station 4; Directed along the local zb3-axis
ElastoDyn['Spn5FLxb3']        = False     # (kN); Blade 3 local flapwise shear force at span station 5; Directed along the local xb3-axis
ElastoDyn['Spn5FLyb3']        = False     # (kN); Blade 3 local edgewise shear force at span station 5; Directed along the local yb3-axis
ElastoDyn['Spn5FLzb3']        = False     # (kN); Blade 3 local axial force at span station 5; Directed along the local zb3-axis
ElastoDyn['Spn6FLxb3']        = False     # (kN); Blade 3 local flapwise shear force at span station 6; Directed along the local xb3-axis
ElastoDyn['Spn6FLyb3']        = False     # (kN); Blade 3 local edgewise shear force at span station 6; Directed along the local yb3-axis
ElastoDyn['Spn6FLzb3']        = False     # (kN); Blade 3 local axial force at span station 6; Directed along the local zb3-axis
ElastoDyn['Spn7FLxb3']        = False     # (kN); Blade 3 local flapwise shear force at span station 7; Directed along the local xb3-axis
ElastoDyn['Spn7FLyb3']        = False     # (kN); Blade 3 local edgewise shear force at span station 7; Directed along the local yb3-axis
ElastoDyn['Spn7FLzb3']        = False     # (kN); Blade 3 local axial force at span station 7; Directed along the local zb3-axis
ElastoDyn['Spn8FLxb3']        = False     # (kN); Blade 3 local flapwise shear force at span station 8; Directed along the local xb3-axis
ElastoDyn['Spn8FLyb3']        = False     # (kN); Blade 3 local edgewise shear force at span station 8; Directed along the local yb3-axis
ElastoDyn['Spn8FLzb3']        = False     # (kN); Blade 3 local axial force at span station 8; Directed along the local zb3-axis
ElastoDyn['Spn9FLxb3']        = False     # (kN); Blade 3 local flapwise shear force at span station 9; Directed along the local xb3-axis
ElastoDyn['Spn9FLyb3']        = False     # (kN); Blade 3 local edgewise shear force at span station 9; Directed along the local yb3-axis
ElastoDyn['Spn9FLzb3']        = False     # (kN); Blade 3 local axial force at span station 9; Directed along the local zb3-axis

# Hub and Rotor Loads
ElastoDyn['LSShftFxa']        = False     # (kN); Low-speed shaft thrust force (this is constant along the shaft and is equivalent to the rotor thrust force); Directed along the xa- and xs-axes
ElastoDyn['LSShftFxs']        = False     # (kN); Low-speed shaft thrust force (this is constant along the shaft and is equivalent to the rotor thrust force); Directed along the xa- and xs-axes
ElastoDyn['LSSGagFxa']        = False     # (kN); Low-speed shaft thrust force (this is constant along the shaft and is equivalent to the rotor thrust force); Directed along the xa- and xs-axes
ElastoDyn['LSSGagFxs']        = False     # (kN); Low-speed shaft thrust force (this is constant along the shaft and is equivalent to the rotor thrust force); Directed along the xa- and xs-axes
ElastoDyn['RotThrust']        = False     # (kN); Low-speed shaft thrust force (this is constant along the shaft and is equivalent to the rotor thrust force); Directed along the xa- and xs-axes
ElastoDyn['LSShftFya']        = False     # (kN); Rotating low-speed shaft shear force (this is constant along the shaft); Directed along the ya-axis
ElastoDyn['LSSGagFya']        = False     # (kN); Rotating low-speed shaft shear force (this is constant along the shaft); Directed along the ya-axis
ElastoDyn['LSShftFza']        = False     # (kN); Rotating low-speed shaft shear force (this is constant along the shaft); Directed along the za-axis
ElastoDyn['LSSGagFza']        = False     # (kN); Rotating low-speed shaft shear force (this is constant along the shaft); Directed along the za-axis
ElastoDyn['LSShftFys']        = True      # (kN); Nonrotating low-speed shaft shear force (this is constant along the shaft); Directed along the ys-axis
ElastoDyn['LSSGagFys']        = False     # (kN); Nonrotating low-speed shaft shear force (this is constant along the shaft); Directed along the ys-axis
ElastoDyn['LSShftFzs']        = True      # (kN); Nonrotating low-speed shaft shear force (this is constant along the shaft); Directed along the zs-axis
ElastoDyn['LSSGagFzs']        = False     # (kN); Nonrotating low-speed shaft shear force (this is constant along the shaft); Directed along the zs-axis
ElastoDyn['LSShftMxa']        = False     # (kN-m); Low-speed shaft torque (this is constant along the shaft and is equivalent to the rotor torque); About the xa- and xs-axes
ElastoDyn['LSShftMxs']        = False     # (kN-m); Low-speed shaft torque (this is constant along the shaft and is equivalent to the rotor torque); About the xa- and xs-axes
ElastoDyn['LSSGagMxa']        = False     # (kN-m); Low-speed shaft torque (this is constant along the shaft and is equivalent to the rotor torque); About the xa- and xs-axes
ElastoDyn['LSSGagMxs']        = False     # (kN-m); Low-speed shaft torque (this is constant along the shaft and is equivalent to the rotor torque); About the xa- and xs-axes
ElastoDyn['RotTorq']          = False     # (kN-m); Low-speed shaft torque (this is constant along the shaft and is equivalent to the rotor torque); About the xa- and xs-axes
ElastoDyn['LSShftTq']         = False     # (kN-m); Low-speed shaft torque (this is constant along the shaft and is equivalent to the rotor torque); About the xa- and xs-axes
ElastoDyn['LSSTipMya']        = False     # (kN-m); Rotating low-speed shaft bending moment at the shaft tip (teeter pin for 2-blader, apex of rotation for 3-blader); About the ya-axis
ElastoDyn['LSSTipMza']        = False     # (kN-m); Rotating low-speed shaft bending moment at the shaft tip (teeter pin for 2-blader, apex of rotation for 3-blader); About the za-axis
ElastoDyn['LSSTipMys']        = True      # (kN-m); Nonrotating low-speed shaft bending moment at the shaft tip (teeter pin for 2-blader, apex of rotation for 3-blader); About the ys-axis
ElastoDyn['LSSTipMzs']        = True      # (kN-m); Nonrotating low-speed shaft bending moment at the shaft tip (teeter pin for 2-blader, apex of rotation for 3-blader); About the zs-axis
ElastoDyn['RotPwr']           = False     # (kW); Rotor power (this is equivalent to the low-speed shaft power); N/A
ElastoDyn['LSShftPwr']        = False     # (kW); Rotor power (this is equivalent to the low-speed shaft power); N/A

# Shaft Strain Gage Loads
ElastoDyn['LSSGagMya']        = False     # (kN-m); Rotating low-speed shaft bending moment at the shaft's strain gage (shaft strain gage located by input ShftGagL); About the ya-axis
ElastoDyn['LSSGagMza']        = False     # (kN-m); Rotating low-speed shaft bending moment at the shaft's strain gage (shaft strain gage located by input ShftGagL); About the za-axis
ElastoDyn['LSSGagMys']        = False     # (kN-m); Nonrotating low-speed shaft bending moment at the shaft's strain gage (shaft strain gage located by input ShftGagL); About the ys-axis
ElastoDyn['LSSGagMzs']        = False     # (kN-m); Nonrotating low-speed shaft bending moment at the shaft's strain gage (shaft strain gage located by input ShftGagL); About the zs-axis

# High-Speed Shaft Loads
ElastoDyn['HSShftTq']         = False     # (kN-m); High-speed shaft torque (this is constant along the shaft); Same sign as LSShftTq / RotTorq / LSShftMxa / LSShftMxs / LSSGagMxa / LSSGagMxs
ElastoDyn['HSSBrTq']          = False     # (kN-m); High-speed shaft brake torque (i.e., the actual moment applied to the high-speed shaft by the brake); Always positive (indicating dissipation of power)
ElastoDyn['HSShftPwr']        = False     # (kW); High-speed shaft power; Same sign as HSShftTq

# Rotor-Furl Bearing Loads
ElastoDyn['RFrlBrM']          = False     # (kN-m); Rotor-furl bearing moment; About the rotor-furl axis

# Tail-Furl Bearing Loads
ElastoDyn['TFrlBrM']          = False     # (kN-m); Tail-furl bearing moment; About the tail-furl axis

# Tower-Top / Yaw Bearing Loads
ElastoDyn['YawBrFxn']         = False     # (kN); Rotating (with nacelle) tower-top / yaw bearing shear force; Directed along the xn-axis
ElastoDyn['YawBrFyn']         = False     # (kN); Rotating (with nacelle) tower-top / yaw bearing shear force; Directed along the yn-axis
ElastoDyn['YawBrFzn']         = False     # (kN); Tower-top / yaw bearing axial force; Directed along the zn- and zp-axes
ElastoDyn['YawBrFzp']         = False     # (kN); Tower-top / yaw bearing axial force; Directed along the zn- and zp-axes
ElastoDyn['YawBrFxp']         = False     # (kN); Tower-top / yaw bearing fore-aft (nonrotating) shear force; Directed along the xp-axis
ElastoDyn['YawBrFyp']         = False     # (kN); Tower-top / yaw bearing side-to-side (nonrotating) shear force; Directed along the yp-axis
ElastoDyn['YawBrMxn']         = False     # (kN-m); Rotating (with nacelle) tower-top / yaw bearing roll moment; About the xn-axis
ElastoDyn['YawBrMyn']         = False     # (kN-m); Rotating (with nacelle) tower-top / yaw bearing pitch moment; About the yn-axis
ElastoDyn['YawBrMzn']         = False     # (kN-m); Tower-top / yaw bearing yaw moment; About the zn- and zp-axes
ElastoDyn['YawBrMzp']         = False     # (kN-m); Tower-top / yaw bearing yaw moment; About the zn- and zp-axes
ElastoDyn['YawBrMxp']         = False     # (kN-m); Nonrotating tower-top / yaw bearing roll moment; About the xp-axis
ElastoDyn['YawBrMyp']         = False     # (kN-m); Nonrotating tower-top / yaw bearing pitch moment; About the yp-axis

# Yaw Friction
ElastoDyn['YawFriMom']        = False     # (kN-m); Calculated and corrected friction torque on yaw bearing; About the zn- and zp-axes
ElastoDyn['YawFriMfp']        = False     # (kN-m); Yaw friction torque to bring yaw system to a stop at current time step; About the zn- and zp-axes
ElastoDyn['YawFriMz']         = False     # (kN-m); External moment on yaw bearing not including inertial contributions; About the zn- and zp-axes
ElastoDyn['OmegaYF']          = False     # (deg/s); Yaw rate used in YawFriMom calculation; Directed along the zn- and zp-axes
ElastoDyn['dOmegaYF']         = False     # (deg/s^2); Yaw acceleration used in YawFriMom calculation; Directed along the zn- and zp-axes

# Tower Base Loads
ElastoDyn['TwrBsFxt']         = False     # (kN); Tower base fore-aft shear force; Directed along the xt-axis
ElastoDyn['TwrBsFyt']         = False     # (kN); Tower base side-to-side shear force; Directed along the yt-axis
ElastoDyn['TwrBsFzt']         = False     # (kN); Tower base axial force; Directed along the zt-axis
ElastoDyn['TwrBsMxt']         = False     # (kN-m); Tower base roll (or side-to-side) moment (i.e., the moment caused by side-to-side forces); About the xt-axis
ElastoDyn['TwrBsMyt']         = True      # (kN-m); Tower base pitching (or fore-aft) moment (i.e., the moment caused by fore-aft forces); About the yt-axis
ElastoDyn['TwrBsMzt']         = False     # (kN-m); Tower base yaw (or torsional) moment; About the zt-axis

# Local Tower Loads
ElastoDyn['TwHt1MLxt']        = False     # (kN-m); Local tower roll (or side-to-side) moment of tower gage 1; About the local xt-axis
ElastoDyn['TwHt1MLyt']        = False     # (kN-m); Local tower pitching (or fore-aft) moment of tower gage 1; About the local yt-axis
ElastoDyn['TwHt1MLzt']        = False     # (kN-m); Local tower yaw (or torsional) moment of tower gage 1; About the local zt-axis
ElastoDyn['TwHt2MLxt']        = False     # (kN-m); Local tower roll (or side-to-side) moment of tower gage 2; About the local xt-axis
ElastoDyn['TwHt2MLyt']        = False     # (kN-m); Local tower pitching (or fore-aft) moment of tower gage 2; About the local yt-axis
ElastoDyn['TwHt2MLzt']        = False     # (kN-m); Local tower yaw (or torsional) moment of tower gage 2; About the local zt-axis
ElastoDyn['TwHt3MLxt']        = False     # (kN-m); Local tower roll (or side-to-side) moment of tower gage 3; About the local xt-axis
ElastoDyn['TwHt3MLyt']        = False     # (kN-m); Local tower pitching (or fore-aft) moment of tower gage 3; About the local yt-axis
ElastoDyn['TwHt3MLzt']        = False     # (kN-m); Local tower yaw (or torsional) moment of tower gage 3; About the local zt-axis
ElastoDyn['TwHt4MLxt']        = False     # (kN-m); Local tower roll (or side-to-side) moment of tower gage 4; About the local xt-axis
ElastoDyn['TwHt4MLyt']        = False     # (kN-m); Local tower pitching (or fore-aft) moment of tower gage 4; About the local yt-axis
ElastoDyn['TwHt4MLzt']        = False     # (kN-m); Local tower yaw (or torsional) moment of tower gage 4; About the local zt-axis
ElastoDyn['TwHt5MLxt']        = False     # (kN-m); Local tower roll (or side-to-side) moment of tower gage 5; About the local xt-axis
ElastoDyn['TwHt5MLyt']        = False     # (kN-m); Local tower pitching (or fore-aft) moment of tower gage 5; About the local yt-axis
ElastoDyn['TwHt5MLzt']        = False     # (kN-m); Local tower yaw (or torsional) moment of tower gage 5; About the local zt-axis
ElastoDyn['TwHt6MLxt']        = False     # (kN-m); Local tower roll (or side-to-side) moment of tower gage 6; About the local xt-axis
ElastoDyn['TwHt6MLyt']        = False     # (kN-m); Local tower pitching (or fore-aft) moment of tower gage 6; About the local yt-axis
ElastoDyn['TwHt6MLzt']        = False     # (kN-m); Local tower yaw (or torsional) moment of tower gage 6; About the local zt-axis
ElastoDyn['TwHt7MLxt']        = False     # (kN-m); Local tower roll (or side-to-side) moment of tower gage 7; About the local xt-axis
ElastoDyn['TwHt7MLyt']        = False     # (kN-m); Local tower pitching (or fore-aft) moment of tower gage 7; About the local yt-axis
ElastoDyn['TwHt7MLzt']        = False     # (kN-m); Local tower yaw (or torsional) moment of tower gage 7; About the local zt-axis
ElastoDyn['TwHt8MLxt']        = False     # (kN-m); Local tower roll (or side-to-side) moment of tower gage 8; About the local xt-axis
ElastoDyn['TwHt8MLyt']        = False     # (kN-m); Local tower pitching (or fore-aft) moment of tower gage 8; About the local yt-axis
ElastoDyn['TwHt8MLzt']        = False     # (kN-m); Local tower yaw (or torsional) moment of tower gage 8; About the local zt-axis
ElastoDyn['TwHt9MLxt']        = False     # (kN-m); Local tower roll (or side-to-side) moment of tower gage 9; About the local xt-axis
ElastoDyn['TwHt9MLyt']        = False     # (kN-m); Local tower pitching (or fore-aft) moment of tower gage 9; About the local yt-axis
ElastoDyn['TwHt9MLzt']        = False     # (kN-m); Local tower yaw (or torsional) moment of tower gage 9; About the local zt-axis
ElastoDyn['TwHt1FLxt']        = False     # (kN); Local tower roll (or side-to-side) force of tower gage 1; About the local xt-axis
ElastoDyn['TwHt1FLyt']        = False     # (kN); Local tower pitching (or fore-aft) force of tower gage 1; About the local yt-axis
ElastoDyn['TwHt1FLzt']        = False     # (kN); Local tower yaw (or torsional) force of tower gage 1; About the local zt-axis
ElastoDyn['TwHt2FLxt']        = False     # (kN); Local tower roll (or side-to-side) force of tower gage 2; About the local xt-axis
ElastoDyn['TwHt2FLyt']        = False     # (kN); Local tower pitching (or fore-aft) force of tower gage 2; About the local yt-axis
ElastoDyn['TwHt2FLzt']        = False     # (kN); Local tower yaw (or torsional) force of tower gage 2; About the local zt-axis
ElastoDyn['TwHt3FLxt']        = False     # (kN); Local tower roll (or side-to-side) force of tower gage 3; About the local xt-axis
ElastoDyn['TwHt3FLyt']        = False     # (kN); Local tower pitching (or fore-aft) force of tower gage 3; About the local yt-axis
ElastoDyn['TwHt3FLzt']        = False     # (kN); Local tower yaw (or torsional) force of tower gage 3; About the local zt-axis
ElastoDyn['TwHt4FLxt']        = False     # (kN); Local tower roll (or side-to-side) force of tower gage 4; About the local xt-axis
ElastoDyn['TwHt4FLyt']        = False     # (kN); Local tower pitching (or fore-aft) force of tower gage 4; About the local yt-axis
ElastoDyn['TwHt4FLzt']        = False     # (kN); Local tower yaw (or torsional) force of tower gage 4; About the local zt-axis
ElastoDyn['TwHt5FLxt']        = False     # (kN); Local tower roll (or side-to-side) force of tower gage 5; About the local xt-axis
ElastoDyn['TwHt5FLyt']        = False     # (kN); Local tower pitching (or fore-aft) force of tower gage 5; About the local yt-axis
ElastoDyn['TwHt5FLzt']        = False     # (kN); Local tower yaw (or torsional) force of tower gage 5; About the local zt-axis
ElastoDyn['TwHt6FLxt']        = False     # (kN); Local tower roll (or side-to-side) force of tower gage 6; About the local xt-axis
ElastoDyn['TwHt6FLyt']        = False     # (kN); Local tower pitching (or fore-aft) force of tower gage 6; About the local yt-axis
ElastoDyn['TwHt6FLzt']        = False     # (kN); Local tower yaw (or torsional) force of tower gage 6; About the local zt-axis
ElastoDyn['TwHt7FLxt']        = False     # (kN); Local tower roll (or side-to-side) force of tower gage 7; About the local xt-axis
ElastoDyn['TwHt7FLyt']        = False     # (kN); Local tower pitching (or fore-aft) force of tower gage 7; About the local yt-axis
ElastoDyn['TwHt7FLzt']        = False     # (kN); Local tower yaw (or torsional) force of tower gage 7; About the local zt-axis
ElastoDyn['TwHt8FLxt']        = False     # (kN); Local tower roll (or side-to-side) force of tower gage 8; About the local xt-axis
ElastoDyn['TwHt8FLyt']        = False     # (kN); Local tower pitching (or fore-aft) force of tower gage 8; About the local yt-axis
ElastoDyn['TwHt8FLzt']        = False     # (kN); Local tower yaw (or torsional) force of tower gage 8; About the local zt-axis
ElastoDyn['TwHt9FLxt']        = False     # (kN); Local tower roll (or side-to-side) force of tower gage 9; About the local xt-axis
ElastoDyn['TwHt9FLyt']        = False     # (kN); Local tower pitching (or fore-aft) force of tower gage 9; About the local yt-axis
ElastoDyn['TwHt9FLzt']        = False     # (kN); Local tower yaw (or torsional) force of tower gage 9; About the local zt-axis

# Internal Degrees of Freedom
ElastoDyn['Q_B1E1']           = False     # (m); Displacement of 1st edgewise bending-mode DOF of blade 1; 
ElastoDyn['Q_B2E1']           = False     # (m); Displacement of 1st edgewise bending-mode DOF of blade 2; 
ElastoDyn['Q_B3E1']           = False     # (m); Displacement of 1st edgewise bending-mode DOF of blade 3; 
ElastoDyn['Q_B1F1']           = False     # (m); Displacement of 1st flapwise bending-mode DOF of blade 1; 
ElastoDyn['Q_B2F1']           = False     # (m); Displacement of 1st flapwise bending-mode DOF of blade 2; 
ElastoDyn['Q_B3F1']           = False     # (m); Displacement of 1st flapwise bending-mode DOF of blade 3; 
ElastoDyn['Q_B1F2']           = False     # (m); Displacement of 2nd flapwise bending-mode DOF of blade 1; 
ElastoDyn['Q_B2F2']           = False     # (m); Displacement of 2nd flapwise bending-mode DOF of blade 2; 
ElastoDyn['Q_B3F2']           = False     # (m); Displacement of 2nd flapwise bending-mode DOF of blade 3; 
ElastoDyn['Q_Teet']           = False     # (rad); Displacement of hub teetering DOF; 
ElastoDyn['Q_DrTr']           = False     # (rad); Displacement of drivetrain rotational-flexibility DOF; 
ElastoDyn['Q_GeAz']           = False     # (rad); Displacement of variable speed generator DOF; 
ElastoDyn['Q_RFrl']           = False     # (rad); Displacement of rotor-furl DOF; 
ElastoDyn['Q_TFrl']           = False     # (rad); Displacement of tail-furl DOF; 
ElastoDyn['Q_Yaw']            = False     # (rad); Displacement of nacelle yaw DOF; 
ElastoDyn['Q_TFA1']           = False     # (m); Displacement of 1st tower fore-aft bending mode DOF; 
ElastoDyn['Q_TSS1']           = False     # (m); Displacement of 1st tower side-to-side bending mode DOF; 
ElastoDyn['Q_TFA2']           = False     # (m); Displacement of 2nd tower fore-aft bending mode DOF; 
ElastoDyn['Q_TSS2']           = False     # (m); Displacement of 2nd tower side-to-side bending mode DOF; 
ElastoDyn['Q_Sg']             = False     # (m); Displacement of platform horizontal surge translation DOF; 
ElastoDyn['Q_Sw']             = False     # (m); Displacement of platform horizontal sway translation DOF; 
ElastoDyn['Q_Hv']             = False     # (m); Displacement of platform vertical heave translation DOF; 
ElastoDyn['Q_R']              = False     # (rad); Displacement of platform roll tilt rotation DOF; 
ElastoDyn['Q_P']              = False     # (rad); Displacement of platform pitch tilt rotation DOF; 
ElastoDyn['Q_Y']              = False     # (rad); Displacement of platform yaw rotation DOF; 
ElastoDyn['QD_B1E1']          = False     # (m/s); Velocity of 1st edgewise bending-mode DOF of blade 1; 
ElastoDyn['QD_B2E1']          = False     # (m/s); Velocity of 1st edgewise bending-mode DOF of blade 2; 
ElastoDyn['QD_B3E1']          = False     # (m/s); Velocity of 1st edgewise bending-mode DOF of blade 3; 
ElastoDyn['QD_B1F1']          = False     # (m/s); Velocity of 1st flapwise bending-mode DOF of blade 1; 
ElastoDyn['QD_B2F1']          = False     # (m/s); Velocity of 1st flapwise bending-mode DOF of blade 2; 
ElastoDyn['QD_B3F1']          = False     # (m/s); Velocity of 1st flapwise bending-mode DOF of blade 3; 
ElastoDyn['QD_B1F2']          = False     # (m/s); Velocity of 2nd flapwise bending-mode DOF of blade 1; 
ElastoDyn['QD_B2F2']          = False     # (m/s); Velocity of 2nd flapwise bending-mode DOF of blade 2; 
ElastoDyn['QD_B3F2']          = False     # (m/s); Velocity of 2nd flapwise bending-mode DOF of blade 3; 
ElastoDyn['QD_Teet']          = False     # (rad/s); Velocity of hub teetering DOF; 
ElastoDyn['QD_DrTr']          = False     # (rad/s); Velocity of drivetrain rotational-flexibility DOF; 
ElastoDyn['QD_GeAz']          = False     # (rad/s); Velocity of variable speed generator DOF; 
ElastoDyn['QD_RFrl']          = False     # (rad/s); Velocity of rotor-furl DOF; 
ElastoDyn['QD_TFrl']          = False     # (rad/s); Velocity of tail-furl DOF; 
ElastoDyn['QD_Yaw']           = False     # (rad/s); Velocity of nacelle yaw DOF; 
ElastoDyn['QD_TFA1']          = False     # (m/s); Velocity of 1st tower fore-aft bending mode DOF; 
ElastoDyn['QD_TSS1']          = False     # (m/s); Velocity of 1st tower side-to-side bending mode DOF; 
ElastoDyn['QD_TFA2']          = False     # (m/s); Velocity of 2nd tower fore-aft bending mode DOF; 
ElastoDyn['QD_TSS2']          = False     # (m/s); Velocity of 2nd tower side-to-side bending mode DOF; 
ElastoDyn['QD_Sg']            = False     # (m/s); Velocity of platform horizontal surge translation DOF; 
ElastoDyn['QD_Sw']            = False     # (m/s); Velocity of platform horizontal sway translation DOF; 
ElastoDyn['QD_Hv']            = False     # (m/s); Velocity of platform vertical heave translation DOF; 
ElastoDyn['QD_R']             = False     # (rad/s); Velocity of platform roll tilt rotation DOF; 
ElastoDyn['QD_P']             = False     # (rad/s); Velocity of platform pitch tilt rotation DOF; 
ElastoDyn['QD_Y']             = False     # (rad/s); Velocity of platform yaw rotation DOF; 
ElastoDyn['QD2_B1E1']         = False     # (m/s^2); Acceleration of 1st edgewise bending-mode DOF of blade 1; 
ElastoDyn['QD2_B2E1']         = False     # (m/s^2); Acceleration of 1st edgewise bending-mode DOF of blade 2; 
ElastoDyn['QD2_B3E1']         = False     # (m/s^2); Acceleration of 1st edgewise bending-mode DOF of blade 3; 
ElastoDyn['QD2_B1F1']         = False     # (m/s^2); Acceleration of 1st flapwise bending-mode DOF of blade 1; 
ElastoDyn['QD2_B2F1']         = False     # (m/s^2); Acceleration of 1st flapwise bending-mode DOF of blade 2; 
ElastoDyn['QD2_B3F1']         = False     # (m/s^2); Acceleration of 1st flapwise bending-mode DOF of blade 3; 
ElastoDyn['QD2_B1F2']         = False     # (m/s^2); Acceleration of 2nd flapwise bending-mode DOF of blade 1; 
ElastoDyn['QD2_B2F2']         = False     # (m/s^2); Acceleration of 2nd flapwise bending-mode DOF of blade 2; 
ElastoDyn['QD2_B3F2']         = False     # (m/s^2); Acceleration of 2nd flapwise bending-mode DOF of blade 3; 
ElastoDyn['QD2_Teet']         = False     # (rad/s^2); Acceleration of hub teetering DOF; 
ElastoDyn['QD2_DrTr']         = False     # (rad/s^2); Acceleration of drivetrain rotational-flexibility DOF; 
ElastoDyn['QD2_GeAz']         = False     # (rad/s^2); Acceleration of variable speed generator DOF; 
ElastoDyn['QD2_RFrl']         = False     # (rad/s^2); Acceleration of rotor-furl DOF; 
ElastoDyn['QD2_TFrl']         = False     # (rad/s^2); Acceleration of tail-furl DOF; 
ElastoDyn['QD2_Yaw']          = False     # (rad/s^2); Acceleration of nacelle yaw DOF; 
ElastoDyn['QD2_TFA1']         = False     # (m/s^2); Acceleration of 1st tower fore-aft bending mode DOF; 
ElastoDyn['QD2_TSS1']         = False     # (m/s^2); Acceleration of 1st tower side-to-side bending mode DOF; 
ElastoDyn['QD2_TFA2']         = False     # (m/s^2); Acceleration of 2nd tower fore-aft bending mode DOF; 
ElastoDyn['QD2_TSS2']         = False     # (m/s^2); Acceleration of 2nd tower side-to-side bending mode DOF; 
ElastoDyn['QD2_Sg']           = False     # (m/s^2); Acceleration of platform horizontal surge translation DOF; 
ElastoDyn['QD2_Sw']           = False     # (m/s^2); Acceleration of platform horizontal sway translation DOF; 
ElastoDyn['QD2_Hv']           = False     # (m/s^2); Acceleration of platform vertical heave translation DOF; 
ElastoDyn['QD2_R']            = False     # (rad/s^2); Acceleration of platform roll tilt rotation DOF; 
ElastoDyn['QD2_P']            = False     # (rad/s^2); Acceleration of platform pitch tilt rotation DOF; 
ElastoDyn['QD2_Y']            = False     # (rad/s^2); Acceleration of platform yaw rotation DOF; 


""" InflowWind """
InflowWind = {}

# Wind Motions
InflowWind['Wind1VelX']       = False     # (m/s); X component of wind at user selected wind point 1; Directed along the xi-axis                         
InflowWind['Wind1VelY']       = False     # (m/s); Y component of wind at user selected wind point 1; Directed along the yi-axis                         
InflowWind['Wind1VelZ']       = False     # (m/s); Z component of wind at user selected wind point 1; Directed along the zi-axis                         
InflowWind['Wind2VelX']       = False     # (m/s); X component of wind at user selected wind point 2; Directed along the xi-axis                         
InflowWind['Wind2VelY']       = False     # (m/s); Y component of wind at user selected wind point 2; Directed along the yi-axis                         
InflowWind['Wind2VelZ']       = False     # (m/s); Z component of wind at user selected wind point 2; Directed along the zi-axis                         
InflowWind['Wind3VelX']       = False     # (m/s); X component of wind at user selected wind point 3; Directed along the xi-axis                         
InflowWind['Wind3VelY']       = False     # (m/s); Y component of wind at user selected wind point 3; Directed along the yi-axis                         
InflowWind['Wind3VelZ']       = False     # (m/s); Z component of wind at user selected wind point 3; Directed along the zi-axis                         
InflowWind['Wind4VelX']       = False     # (m/s); X component of wind at user selected wind point 4; Directed along the xi-axis                         
InflowWind['Wind4VelY']       = False     # (m/s); Y component of wind at user selected wind point 4; Directed along the yi-axis                         
InflowWind['Wind4VelZ']       = False     # (m/s); Z component of wind at user selected wind point 4; Directed along the zi-axis                         
InflowWind['Wind5VelX']       = False     # (m/s); X component of wind at user selected wind point 5; Directed along the xi-axis                         
InflowWind['Wind5VelY']       = False     # (m/s); Y component of wind at user selected wind point 5; Directed along the yi-axis                         
InflowWind['Wind5VelZ']       = False     # (m/s); Z component of wind at user selected wind point 5; Directed along the zi-axis                         
InflowWind['Wind6VelX']       = False     # (m/s); X component of wind at user selected wind point 6; Directed along the xi-axis                         
InflowWind['Wind6VelY']       = False     # (m/s); Y component of wind at user selected wind point 6; Directed along the yi-axis                         
InflowWind['Wind6VelZ']       = False     # (m/s); Z component of wind at user selected wind point 6; Directed along the zi-axis                         
InflowWind['Wind7VelX']       = False     # (m/s); X component of wind at user selected wind point 7; Directed along the xi-axis                         
InflowWind['Wind7VelY']       = False     # (m/s); Y component of wind at user selected wind point 7; Directed along the yi-axis                         
InflowWind['Wind7VelZ']       = False     # (m/s); Z component of wind at user selected wind point 7; Directed along the zi-axis                         
InflowWind['Wind8VelX']       = False     # (m/s); X component of wind at user selected wind point 8; Directed along the xi-axis                         
InflowWind['Wind8VelY']       = False     # (m/s); Y component of wind at user selected wind point 8; Directed along the yi-axis                         
InflowWind['Wind8VelZ']       = False     # (m/s); Z component of wind at user selected wind point 8; Directed along the zi-axis                         
InflowWind['Wind9VelX']       = False     # (m/s); X component of wind at user selected wind point 9; Directed along the xi-axis                         
InflowWind['Wind9VelY']       = False     # (m/s); Y component of wind at user selected wind point 9; Directed along the yi-axis                         
InflowWind['Wind9VelZ']       = False     # (m/s); Z component of wind at user selected wind point 9; Directed along the zi-axis                         
InflowWind['WindHubVelX']     = False     # (m/s); X component of wind at (moving) hub point; Directed along the xi-axis                         
InflowWind['WindHubVelY']     = False     # (m/s); Y component of wind at (moving) hub point; Directed along the yi-axis                         
InflowWind['WindHubVelZ']     = False     # (m/s); Z component of wind at (moving) hub point; Directed along the zi-axis                         
InflowWind['WindDiskVelX']    = False     # (m/s); Disk-average X component of wind (at 70% span); Directed along the xi-axis                         
InflowWind['WindDiskVelY']    = False     # (m/s); Disk-average Y component of wind (at 70% span); Directed along the yi-axis                         
InflowWind['WindDiskVelZ']    = False     # (m/s); Disk-average Z component of wind (at 70% span); Directed along the zi-axis                         

# Wind Accelerations
InflowWind['Wind1AccX']       = False     # (m/s); X component of wind at user selected wind point 1; Directed along the xi-axis                         
InflowWind['Wind1AccY']       = False     # (m/s); Y component of wind at user selected wind point 1; Directed along the yi-axis                         
InflowWind['Wind1AccZ']       = False     # (m/s); Z component of wind at user selected wind point 1; Directed along the zi-axis                         
InflowWind['Wind2AccX']       = False     # (m/s); X component of wind at user selected wind point 2; Directed along the xi-axis                         
InflowWind['Wind2AccY']       = False     # (m/s); Y component of wind at user selected wind point 2; Directed along the yi-axis                         
InflowWind['Wind2AccZ']       = False     # (m/s); Z component of wind at user selected wind point 2; Directed along the zi-axis                         
InflowWind['Wind3AccX']       = False     # (m/s); X component of wind at user selected wind point 3; Directed along the xi-axis                         
InflowWind['Wind3AccY']       = False     # (m/s); Y component of wind at user selected wind point 3; Directed along the yi-axis                         
InflowWind['Wind3AccZ']       = False     # (m/s); Z component of wind at user selected wind point 3; Directed along the zi-axis                         
InflowWind['Wind4AccX']       = False     # (m/s); X component of wind at user selected wind point 4; Directed along the xi-axis                         
InflowWind['Wind4AccY']       = False     # (m/s); Y component of wind at user selected wind point 4; Directed along the yi-axis                         
InflowWind['Wind4AccZ']       = False     # (m/s); Z component of wind at user selected wind point 4; Directed along the zi-axis                         
InflowWind['Wind5AccX']       = False     # (m/s); X component of wind at user selected wind point 5; Directed along the xi-axis                         
InflowWind['Wind5AccY']       = False     # (m/s); Y component of wind at user selected wind point 5; Directed along the yi-axis                         
InflowWind['Wind5AccZ']       = False     # (m/s); Z component of wind at user selected wind point 5; Directed along the zi-axis                         
InflowWind['Wind6AccX']       = False     # (m/s); X component of wind at user selected wind point 6; Directed along the xi-axis                         
InflowWind['Wind6AccY']       = False     # (m/s); Y component of wind at user selected wind point 6; Directed along the yi-axis                         
InflowWind['Wind6AccZ']       = False     # (m/s); Z component of wind at user selected wind point 6; Directed along the zi-axis                         
InflowWind['Wind7AccX']       = False     # (m/s); X component of wind at user selected wind point 7; Directed along the xi-axis                         
InflowWind['Wind7AccY']       = False     # (m/s); Y component of wind at user selected wind point 7; Directed along the yi-axis                         
InflowWind['Wind7AccZ']       = False     # (m/s); Z component of wind at user selected wind point 7; Directed along the zi-axis                         
InflowWind['Wind8AccX']       = False     # (m/s); X component of wind at user selected wind point 8; Directed along the xi-axis                         
InflowWind['Wind8AccY']       = False     # (m/s); Y component of wind at user selected wind point 8; Directed along the yi-axis                         
InflowWind['Wind8AccZ']       = False     # (m/s); Z component of wind at user selected wind point 8; Directed along the zi-axis                         
InflowWind['Wind9AccX']       = False     # (m/s); X component of wind at user selected wind point 9; Directed along the xi-axis                         
InflowWind['Wind9AccY']       = False     # (m/s); Y component of wind at user selected wind point 9; Directed along the yi-axis                         
InflowWind['Wind9AccZ']       = False     # (m/s); Z component of wind at user selected wind point 9; Directed along the zi-axis                         

# Wind Magnitude and Direction
InflowWind['Wind1VelXY']      = False     # (m/s); XY (horizontal) wind magnitude at user selected wind point 1; 
InflowWind['Wind2VelXY']      = False     # (m/s); XY (horizontal) wind magnitude at user selected wind point 2; 
InflowWind['Wind3VelXY']      = False     # (m/s); XY (horizontal) wind magnitude at user selected wind point 3; 
InflowWind['Wind4VelXY']      = False     # (m/s); XY (horizontal) wind magnitude at user selected wind point 4; 
InflowWind['Wind5VelXY']      = False     # (m/s); XY (horizontal) wind magnitude at user selected wind point 5; 
InflowWind['Wind6VelXY']      = False     # (m/s); XY (horizontal) wind magnitude at user selected wind point 6; 
InflowWind['Wind7VelXY']      = False     # (m/s); XY (horizontal) wind magnitude at user selected wind point 7; 
InflowWind['Wind8VelXY']      = False     # (m/s); XY (horizontal) wind magnitude at user selected wind point 8; 
InflowWind['Wind9VelXY']      = False     # (m/s); XY (horizontal) wind magnitude at user selected wind point 9; 
InflowWind['WindHubVelXY']    = False     # (m/s); XY (horizontal) component of wind at (moving) hub point; 
InflowWind['WindDiskVelXY']   = False     # (m/s); XY (horizontal) component of disk-average wind (at 70% span); 
InflowWind['Wind1VelMag']     = False     # (m/s); wind magnitude at user selected wind point 1; 
InflowWind['Wind2VelMag']     = False     # (m/s); wind magnitude at user selected wind point 2; 
InflowWind['Wind3VelMag']     = False     # (m/s); wind magnitude at user selected wind point 3; 
InflowWind['Wind4VelMag']     = False     # (m/s); wind magnitude at user selected wind point 4; 
InflowWind['Wind5VelMag']     = False     # (m/s); wind magnitude at user selected wind point 5; 
InflowWind['Wind6VelMag']     = False     # (m/s); wind magnitude at user selected wind point 6; 
InflowWind['Wind7VelMag']     = False     # (m/s); wind magnitude at user selected wind point 7; 
InflowWind['Wind8VelMag']     = False     # (m/s); wind magnitude at user selected wind point 8; 
InflowWind['Wind9VelMag']     = False     # (m/s); wind magnitude at user selected wind point 9; 
InflowWind['WindHubVelMag']   = False     # (m/s); wind magnitude at (moving) hub point; 
InflowWind['WindDiskVelMag']  = False     # (m/s); wind magnitude of disk-average wind (at 70% span); 
InflowWind['Wind1AngXY']      = False     # (deg); Angle between X and Y wind velocity components at user selected wind point 1; 
InflowWind['Wind2AngXY']      = False     # (deg); Angle between X and Y wind velocity components at user selected wind point 2; 
InflowWind['Wind3AngXY']      = False     # (deg); Angle between X and Y wind velocity components at user selected wind point 3; 
InflowWind['Wind4AngXY']      = False     # (deg); Angle between X and Y wind velocity components at user selected wind point 4; 
InflowWind['Wind5AngXY']      = False     # (deg); Angle between X and Y wind velocity components at user selected wind point 5; 
InflowWind['Wind6AngXY']      = False     # (deg); Angle between X and Y wind velocity components at user selected wind point 6; 
InflowWind['Wind7AngXY']      = False     # (deg); Angle between X and Y wind velocity components at user selected wind point 7; 
InflowWind['Wind8AngXY']      = False     # (deg); Angle between X and Y wind velocity components at user selected wind point 8; 
InflowWind['Wind9AngXY']      = False     # (deg); Angle between X and Y wind velocity components at user selected wind point 9; 
InflowWind['WindHubAngXY']    = False     # (deg); Angle between X and Y wind velocity components at (moving) hub point; 
InflowWind['WindDiskAngXY']   = False     # (deg); Angle between X and Y wind velocity components of disk-average wind (at 70% span); 

# Wind Sensor Measurements
InflowWind['WindMeas1']       = False     # (m/s); Wind measurement at sensor 1; Defined by sensor
InflowWind['WindMeas2']       = False     # (m/s); Wind measurement at sensor 2; Defined by sensor
InflowWind['WindMeas3']       = False     # (m/s); Wind measurement at sensor 3; Defined by sensor
InflowWind['WindMeas4']       = False     # (m/s); Wind measurement at sensor 4; Defined by sensor
InflowWind['WindMeas5']       = False     # (m/s); Wind measurement at sensor 5; Defined by sensor


""" ServoDyn """
ServoDyn = {}

# Airfoil control
ServoDyn['BlAirFlC1']         = False     # (-); Blade 1 airfoil control  command; Same units as provided in airfoil tables of AD15 (UserProp)
ServoDyn['BlFlap1']           = False     # (-); Blade 1 airfoil control  command; Same units as provided in airfoil tables of AD15 (UserProp)
ServoDyn['BlAirFlC2']         = False     # (-); Blade 2 airfoil control  command; Same units as provided in airfoil tables of AD15 (UserProp)
ServoDyn['BlFlap2']           = False     # (-); Blade 2 airfoil control  command; Same units as provided in airfoil tables of AD15 (UserProp)
ServoDyn['BlAirFlC3']         = False     # (-); Blade 3 airfoil control  command; Same units as provided in airfoil tables of AD15 (UserProp)
ServoDyn['BlFlap3']           = False     # (-); Blade 3 airfoil control  command; Same units as provided in airfoil tables of AD15 (UserProp)

# Pitch Control
ServoDyn['BlPitchC1']         = False     # (deg); Blade 1 pitch angle command; Positive towards feather about the minus zc1- and minus zb1-axes
ServoDyn['BlPitchC2']         = False     # (deg); Blade 2 pitch angle command; Positive towards feather about the minus zc2- and minus zb2-axes
ServoDyn['BlPitchC3']         = False     # (deg); Blade 3 pitch angle command; Positive towards feather about the minus zc3- and minus zb3-axes

# Generator and Torque Control
ServoDyn['GenTq']             = False     # (kN-m); Electrical generator torque; Positive reflects power extracted and negative represents a motoring-up situation (power input)
ServoDyn['GenPwr']            = False     # (kW); Electrical generator power; Same sign as GenTq

# High Speed Shaft Brake
ServoDyn['HSSBrTqC']          = False     # (kN-m); High-speed shaft brake torque command (i.e., the commanded moment applied to the high-speed shaft by the brake); Always positive (indicating dissipation of power)

# Nacelle Yaw Control
ServoDyn['YawMomCom']         = False     # (kN-m); Nacelle yaw moment command; About the zl- and zp-axes
ServoDyn['YawMom']            = False     # (kN-m); Nacelle yaw moment command; About the zl- and zp-axes

# Nacelle Structural Control  (StC)
ServoDyn['NStC1_XQ']          = False     # (m); Nacelle StC #1  -- X position (displacement); Relative to rest position in StC reference frame
ServoDyn['NStC1_XQD']         = False     # (m/s); Nacelle StC #1 -- X velocity; Relative to nacelle in StC reference frame
ServoDyn['NStC1_YQ']          = False     # (m); Nacelle StC #1 -- Y position (displacement); Relative to rest position in StC reference frame
ServoDyn['NStC1_YQD']         = False     # (m/s); Nacelle StC #1 -- Y velocity; Relative to nacelle in StC reference frame
ServoDyn['NStC1_ZQ']          = False     # (m); Nacelle StC #1 -- Z position (displacement); Relative to rest position in StC reference frame
ServoDyn['NStC1_ZQD']         = False     # (m/s); Nacelle StC #1 -- Z velocity; Relative to nacelle in StC reference frame
ServoDyn['NStC1_Fxi']         = False     # (kN); Nacelle StC #1 -- X resulting force; Inertial (global) coordinates
ServoDyn['NStC1_Fyi']         = False     # (kN); Nacelle StC #1 -- Y resulting force; Inertial (global) coordinates
ServoDyn['NStC1_Fzi']         = False     # (kN); Nacelle StC #1 -- Z resulting force; Inertial (global) coordinates
ServoDyn['NStC1_Mxi']         = False     # (kN-m); Nacelle StC #1 -- X resulting moment; Inertial (global) coordinates
ServoDyn['NStC1_Myi']         = False     # (kN-m); Nacelle StC #1 -- Y resulting moment; Inertial (global) coordinates
ServoDyn['NStC1_Mzi']         = False     # (kN-m); Nacelle StC #1 -- Z resulting moment; Inertial (global) coordinates
ServoDyn['NStC1_Fxl']         = False     # (kN); Nacelle StC #1 -- X resulting force; Local StC coordinates
ServoDyn['NStC1_Fyl']         = False     # (kN); Nacelle StC #1 -- Y resulting force; Local StC coordinates
ServoDyn['NStC1_Fzl']         = False     # (kN); Nacelle StC #1 -- Z resulting force; Local StC coordinates
ServoDyn['NStC1_Mxl']         = False     # (kN-m); Nacelle StC #1 -- X resulting moment; Local StC coordinates
ServoDyn['NStC1_Myl']         = False     # (kN-m); Nacelle StC #1 -- Y resulting moment; Local StC coordinates
ServoDyn['NStC1_Mzl']         = False     # (kN-m); Nacelle StC #1 -- Z resulting moment; Local StC coordinates
ServoDyn['NStC2_XQ']          = False     # (m); Nacelle StC #2  -- X position (displacement); Relative to rest position in StC reference frame
ServoDyn['NStC2_XQD']         = False     # (m/s); Nacelle StC #2 -- X velocity; Relative to nacelle in StC reference frame
ServoDyn['NStC2_YQ']          = False     # (m); Nacelle StC #2 -- Y position (displacement); Relative to rest position in StC reference frame
ServoDyn['NStC2_YQD']         = False     # (m/s); Nacelle StC #2 -- Y velocity; Relative to nacelle in StC reference frame
ServoDyn['NStC2_ZQ']          = False     # (m); Nacelle StC #2 -- Z position (displacement); Relative to rest position in StC reference frame
ServoDyn['NStC2_ZQD']         = False     # (m/s); Nacelle StC #2 -- Z velocity; Relative to nacelle in StC reference frame
ServoDyn['NStC2_Fxi']         = False     # (kN); Nacelle StC #2 -- X resulting force; Inertial (global) coordinates
ServoDyn['NStC2_Fyi']         = False     # (kN); Nacelle StC #2 -- Y resulting force; Inertial (global) coordinates
ServoDyn['NStC2_Fzi']         = False     # (kN); Nacelle StC #2 -- Z resulting force; Inertial (global) coordinates
ServoDyn['NStC2_Mxi']         = False     # (kN-m); Nacelle StC #2 -- X resulting moment; Inertial (global) coordinates
ServoDyn['NStC2_Myi']         = False     # (kN-m); Nacelle StC #2 -- Y resulting moment; Inertial (global) coordinates
ServoDyn['NStC2_Mzi']         = False     # (kN-m); Nacelle StC #2 -- Z resulting moment; Inertial (global) coordinates
ServoDyn['NStC2_Fxl']         = False     # (kN); Nacelle StC #2 -- X resulting force; Local StC coordinates
ServoDyn['NStC2_Fyl']         = False     # (kN); Nacelle StC #2 -- Y resulting force; Local StC coordinates
ServoDyn['NStC2_Fzl']         = False     # (kN); Nacelle StC #2 -- Z resulting force; Local StC coordinates
ServoDyn['NStC2_Mxl']         = False     # (kN-m); Nacelle StC #2 -- X resulting moment; Local StC coordinates
ServoDyn['NStC2_Myl']         = False     # (kN-m); Nacelle StC #2 -- Y resulting moment; Local StC coordinates
ServoDyn['NStC2_Mzl']         = False     # (kN-m); Nacelle StC #2 -- Z resulting moment; Local StC coordinates
ServoDyn['NStC3_XQ']          = False     # (m); Nacelle StC #3  -- X position (displacement); Relative to rest position in StC reference frame
ServoDyn['NStC3_XQD']         = False     # (m/s); Nacelle StC #3 -- X velocity; Relative to nacelle in StC reference frame
ServoDyn['NStC3_YQ']          = False     # (m); Nacelle StC #3 -- Y position (displacement); Relative to rest position in StC reference frame
ServoDyn['NStC3_YQD']         = False     # (m/s); Nacelle StC #3 -- Y velocity; Relative to nacelle in StC reference frame
ServoDyn['NStC3_ZQ']          = False     # (m); Nacelle StC #3 -- Z position (displacement); Relative to rest position in StC reference frame
ServoDyn['NStC3_ZQD']         = False     # (m/s); Nacelle StC #3 -- Z velocity; Relative to nacelle in StC reference frame
ServoDyn['NStC3_Fxi']         = False     # (kN); Nacelle StC #3 -- X resulting force; Inertial (global) coordinates
ServoDyn['NStC3_Fyi']         = False     # (kN); Nacelle StC #3 -- Y resulting force; Inertial (global) coordinates
ServoDyn['NStC3_Fzi']         = False     # (kN); Nacelle StC #3 -- Z resulting force; Inertial (global) coordinates
ServoDyn['NStC3_Mxi']         = False     # (kN-m); Nacelle StC #3 -- X resulting moment; Inertial (global) coordinates
ServoDyn['NStC3_Myi']         = False     # (kN-m); Nacelle StC #3 -- Y resulting moment; Inertial (global) coordinates
ServoDyn['NStC3_Mzi']         = False     # (kN-m); Nacelle StC #3 -- Z resulting moment; Inertial (global) coordinates
ServoDyn['NStC3_Fxl']         = False     # (kN); Nacelle StC #3 -- X resulting force; Local StC coordinates
ServoDyn['NStC3_Fyl']         = False     # (kN); Nacelle StC #3 -- Y resulting force; Local StC coordinates
ServoDyn['NStC3_Fzl']         = False     # (kN); Nacelle StC #3 -- Z resulting force; Local StC coordinates
ServoDyn['NStC3_Mxl']         = False     # (kN-m); Nacelle StC #3 -- X resulting moment; Local StC coordinates
ServoDyn['NStC3_Myl']         = False     # (kN-m); Nacelle StC #3 -- Y resulting moment; Local StC coordinates
ServoDyn['NStC3_Mzl']         = False     # (kN-m); Nacelle StC #3 -- Z resulting moment; Local StC coordinates
ServoDyn['NStC4_XQ']          = False     # (m); Nacelle StC #4  -- X position (displacement); Relative to rest position in StC reference frame
ServoDyn['NStC4_XQD']         = False     # (m/s); Nacelle StC #4 -- X velocity; Relative to nacelle in StC reference frame
ServoDyn['NStC4_YQ']          = False     # (m); Nacelle StC #4 -- Y position (displacement); Relative to rest position in StC reference frame
ServoDyn['NStC4_YQD']         = False     # (m/s); Nacelle StC #4 -- Y velocity; Relative to nacelle in StC reference frame
ServoDyn['NStC4_ZQ']          = False     # (m); Nacelle StC #4 -- Z position (displacement); Relative to rest position in StC reference frame
ServoDyn['NStC4_ZQD']         = False     # (m/s); Nacelle StC #4 -- Z velocity; Relative to nacelle in StC reference frame
ServoDyn['NStC4_Fxi']         = False     # (kN); Nacelle StC #4 -- X resulting force; Inertial (global) coordinates
ServoDyn['NStC4_Fyi']         = False     # (kN); Nacelle StC #4 -- Y resulting force; Inertial (global) coordinates
ServoDyn['NStC4_Fzi']         = False     # (kN); Nacelle StC #4 -- Z resulting force; Inertial (global) coordinates
ServoDyn['NStC4_Mxi']         = False     # (kN-m); Nacelle StC #4 -- X resulting moment; Inertial (global) coordinates
ServoDyn['NStC4_Myi']         = False     # (kN-m); Nacelle StC #4 -- Y resulting moment; Inertial (global) coordinates
ServoDyn['NStC4_Mzi']         = False     # (kN-m); Nacelle StC #4 -- Z resulting moment; Inertial (global) coordinates
ServoDyn['NStC4_Fxl']         = False     # (kN); Nacelle StC #4 -- X resulting force; Local StC coordinates
ServoDyn['NStC4_Fyl']         = False     # (kN); Nacelle StC #4 -- Y resulting force; Local StC coordinates
ServoDyn['NStC4_Fzl']         = False     # (kN); Nacelle StC #4 -- Z resulting force; Local StC coordinates
ServoDyn['NStC4_Mxl']         = False     # (kN-m); Nacelle StC #4 -- X resulting moment; Local StC coordinates
ServoDyn['NStC4_Myl']         = False     # (kN-m); Nacelle StC #4 -- Y resulting moment; Local StC coordinates
ServoDyn['NStC4_Mzl']         = False     # (kN-m); Nacelle StC #4 -- Z resulting moment; Local StC coordinates

# Tower Structural Control  (StC)
ServoDyn['TStC1_XQ']          = False     # (m); Tower StC #1  -- X position (displacement); Relative to rest position in StC reference frame
ServoDyn['TStC1_XQD']         = False     # (m/s); Tower StC #1 -- X velocity; Relative to nacelle in StC reference frame
ServoDyn['TStC1_YQ']          = False     # (m); Tower StC #1 -- Y position (displacement); Relative to rest position in StC reference frame
ServoDyn['TStC1_YQD']         = False     # (m/s); Tower StC #1 -- Y velocity; Relative to nacelle in StC reference frame
ServoDyn['TStC1_ZQ']          = False     # (m); Tower StC #1 -- Z position (displacement); Relative to rest position in StC reference frame
ServoDyn['TStC1_ZQD']         = False     # (m/s); Tower StC #1 -- Z velocity; Relative to nacelle in StC reference frame
ServoDyn['TStC1_Fxi']         = False     # (kN); Tower StC #1 -- X resulting force; Inertial (global) coordinates
ServoDyn['TStC1_Fyi']         = False     # (kN); Tower StC #1 -- Y resulting force; Inertial (global) coordinates
ServoDyn['TStC1_Fzi']         = False     # (kN); Tower StC #1 -- Z resulting force; Inertial (global) coordinates
ServoDyn['TStC1_Mxi']         = False     # (kN-m); Tower StC #1 -- X resulting moment; Inertial (global) coordinates
ServoDyn['TStC1_Myi']         = False     # (kN-m); Tower StC #1 -- Y resulting moment; Inertial (global) coordinates
ServoDyn['TStC1_Mzi']         = False     # (kN-m); Tower StC #1 -- Z resulting moment; Inertial (global) coordinates
ServoDyn['TStC1_Fxl']         = False     # (kN); Tower StC #1 -- X resulting force; Local StC coordinates
ServoDyn['TStC1_Fyl']         = False     # (kN); Tower StC #1 -- Y resulting force; Local StC coordinates
ServoDyn['TStC1_Fzl']         = False     # (kN); Tower StC #1 -- Z resulting force; Local StC coordinates
ServoDyn['TStC1_Mxl']         = False     # (kN-m); Tower StC #1 -- X resulting moment; Local StC coordinates
ServoDyn['TStC1_Myl']         = False     # (kN-m); Tower StC #1 -- Y resulting moment; Local StC coordinates
ServoDyn['TStC1_Mzl']         = False     # (kN-m); Tower StC #1 -- Z resulting moment; Local StC coordinates
ServoDyn['TStC2_XQ']          = False     # (m); Tower StC #2  -- X position (displacement); Relative to rest position in StC reference frame
ServoDyn['TStC2_XQD']         = False     # (m/s); Tower StC #2 -- X velocity; Relative to nacelle in StC reference frame
ServoDyn['TStC2_YQ']          = False     # (m); Tower StC #2 -- Y position (displacement); Relative to rest position in StC reference frame
ServoDyn['TStC2_YQD']         = False     # (m/s); Tower StC #2 -- Y velocity; Relative to nacelle in StC reference frame
ServoDyn['TStC2_ZQ']          = False     # (m); Tower StC #2 -- Z position (displacement); Relative to rest position in StC reference frame
ServoDyn['TStC2_ZQD']         = False     # (m/s); Tower StC #2 -- Z velocity; Relative to nacelle in StC reference frame
ServoDyn['TStC2_Fxi']         = False     # (kN); Tower StC #2 -- X resulting force; Inertial (global) coordinates
ServoDyn['TStC2_Fyi']         = False     # (kN); Tower StC #2 -- Y resulting force; Inertial (global) coordinates
ServoDyn['TStC2_Fzi']         = False     # (kN); Tower StC #2 -- Z resulting force; Inertial (global) coordinates
ServoDyn['TStC2_Mxi']         = False     # (kN-m); Tower StC #2 -- X resulting moment; Inertial (global) coordinates
ServoDyn['TStC2_Myi']         = False     # (kN-m); Tower StC #2 -- Y resulting moment; Inertial (global) coordinates
ServoDyn['TStC2_Mzi']         = False     # (kN-m); Tower StC #2 -- Z resulting moment; Inertial (global) coordinates
ServoDyn['TStC2_Fxl']         = False     # (kN); Tower StC #2 -- X resulting force; Local StC coordinates
ServoDyn['TStC2_Fyl']         = False     # (kN); Tower StC #2 -- Y resulting force; Local StC coordinates
ServoDyn['TStC2_Fzl']         = False     # (kN); Tower StC #2 -- Z resulting force; Local StC coordinates
ServoDyn['TStC2_Mxl']         = False     # (kN-m); Tower StC #2 -- X resulting moment; Local StC coordinates
ServoDyn['TStC2_Myl']         = False     # (kN-m); Tower StC #2 -- Y resulting moment; Local StC coordinates
ServoDyn['TStC2_Mzl']         = False     # (kN-m); Tower StC #2 -- Z resulting moment; Local StC coordinates
ServoDyn['TStC3_XQ']          = False     # (m); Tower StC #3  -- X position (displacement); Relative to rest position in StC reference frame
ServoDyn['TStC3_XQD']         = False     # (m/s); Tower StC #3 -- X velocity; Relative to nacelle in StC reference frame
ServoDyn['TStC3_YQ']          = False     # (m); Tower StC #3 -- Y position (displacement); Relative to rest position in StC reference frame
ServoDyn['TStC3_YQD']         = False     # (m/s); Tower StC #3 -- Y velocity; Relative to nacelle in StC reference frame
ServoDyn['TStC3_ZQ']          = False     # (m); Tower StC #3 -- Z position (displacement); Relative to rest position in StC reference frame
ServoDyn['TStC3_ZQD']         = False     # (m/s); Tower StC #3 -- Z velocity; Relative to nacelle in StC reference frame
ServoDyn['TStC3_Fxi']         = False     # (kN); Tower StC #3 -- X resulting force; Inertial (global) coordinates
ServoDyn['TStC3_Fyi']         = False     # (kN); Tower StC #3 -- Y resulting force; Inertial (global) coordinates
ServoDyn['TStC3_Fzi']         = False     # (kN); Tower StC #3 -- Z resulting force; Inertial (global) coordinates
ServoDyn['TStC3_Mxi']         = False     # (kN-m); Tower StC #3 -- X resulting moment; Inertial (global) coordinates
ServoDyn['TStC3_Myi']         = False     # (kN-m); Tower StC #3 -- Y resulting moment; Inertial (global) coordinates
ServoDyn['TStC3_Mzi']         = False     # (kN-m); Tower StC #3 -- Z resulting moment; Inertial (global) coordinates
ServoDyn['TStC3_Fxl']         = False     # (kN); Tower StC #3 -- X resulting force; Local StC coordinates
ServoDyn['TStC3_Fyl']         = False     # (kN); Tower StC #3 -- Y resulting force; Local StC coordinates
ServoDyn['TStC3_Fzl']         = False     # (kN); Tower StC #3 -- Z resulting force; Local StC coordinates
ServoDyn['TStC3_Mxl']         = False     # (kN-m); Tower StC #3 -- X resulting moment; Local StC coordinates
ServoDyn['TStC3_Myl']         = False     # (kN-m); Tower StC #3 -- Y resulting moment; Local StC coordinates
ServoDyn['TStC3_Mzl']         = False     # (kN-m); Tower StC #3 -- Z resulting moment; Local StC coordinates
ServoDyn['TStC4_XQ']          = False     # (m); Tower StC #4  -- X position (displacement); Relative to rest position in StC reference frame
ServoDyn['TStC4_XQD']         = False     # (m/s); Tower StC #4 -- X velocity; Relative to nacelle in StC reference frame
ServoDyn['TStC4_YQ']          = False     # (m); Tower StC #4 -- Y position (displacement); Relative to rest position in StC reference frame
ServoDyn['TStC4_YQD']         = False     # (m/s); Tower StC #4 -- Y velocity; Relative to nacelle in StC reference frame
ServoDyn['TStC4_ZQ']          = False     # (m); Tower StC #4 -- Z position (displacement); Relative to rest position in StC reference frame
ServoDyn['TStC4_ZQD']         = False     # (m/s); Tower StC #4 -- Z velocity; Relative to nacelle in StC reference frame
ServoDyn['TStC4_Fxi']         = False     # (kN); Tower StC #4 -- X resulting force; Inertial (global) coordinates
ServoDyn['TStC4_Fyi']         = False     # (kN); Tower StC #4 -- Y resulting force; Inertial (global) coordinates
ServoDyn['TStC4_Fzi']         = False     # (kN); Tower StC #4 -- Z resulting force; Inertial (global) coordinates
ServoDyn['TStC4_Mxi']         = False     # (kN-m); Tower StC #4 -- X resulting moment; Inertial (global) coordinates
ServoDyn['TStC4_Myi']         = False     # (kN-m); Tower StC #4 -- Y resulting moment; Inertial (global) coordinates
ServoDyn['TStC4_Mzi']         = False     # (kN-m); Tower StC #4 -- Z resulting moment; Inertial (global) coordinates
ServoDyn['TStC4_Fxl']         = False     # (kN); Tower StC #4 -- X resulting force; Local StC coordinates
ServoDyn['TStC4_Fyl']         = False     # (kN); Tower StC #4 -- Y resulting force; Local StC coordinates
ServoDyn['TStC4_Fzl']         = False     # (kN); Tower StC #4 -- Z resulting force; Local StC coordinates
ServoDyn['TStC4_Mxl']         = False     # (kN-m); Tower StC #4 -- X resulting moment; Local StC coordinates
ServoDyn['TStC4_Myl']         = False     # (kN-m); Tower StC #4 -- Y resulting moment; Local StC coordinates
ServoDyn['TStC4_Mzl']         = False     # (kN-m); Tower StC #4 -- Z resulting moment; Local StC coordinates

# Blade  Structural Control  (StC)
ServoDyn['BStC1_B1_XQ']       = False     # (m); Blade StC #1  Blade #1 -- X position (displacement); Relative to rest position in StC reference frame
ServoDyn['BStC1_B1_XQD']      = False     # (m/s); Blade StC #1 Blade #1 -- X velocity; Relative to nacelle in StC reference frame
ServoDyn['BStC1_B1_YQ']       = False     # (m); Blade StC #1 Blade #1 -- Y position (displacement); Relative to rest position in StC reference frame
ServoDyn['BStC1_B1_YQD']      = False     # (m/s); Blade StC #1 Blade #1 -- Y velocity; Relative to nacelle in StC reference frame
ServoDyn['BStC1_B1_ZQ']       = False     # (m); Blade StC #1 Blade #1 -- Z position (displacement); Relative to rest position in StC reference frame
ServoDyn['BStC1_B1_ZQD']      = False     # (m/s); Blade StC #1 Blade #1 -- Z velocity; Relative to nacelle in StC reference frame
ServoDyn['BStC1_B1_Fxi']      = False     # (kN); Blade StC #1 Blade #1 -- X resulting force; Inertial (global) coordinates
ServoDyn['BStC1_B1_Fyi']      = False     # (kN); Blade StC #1 Blade #1 -- Y resulting force; Inertial (global) coordinates
ServoDyn['BStC1_B1_Fzi']      = False     # (kN); Blade StC #1 Blade #1 -- Z resulting force; Inertial (global) coordinates
ServoDyn['BStC1_B1_Mxi']      = False     # (kN-m); Blade StC #1 Blade #1 -- X resulting moment; Inertial (global) coordinates
ServoDyn['BStC1_B1_Myi']      = False     # (kN-m); Blade StC #1 Blade #1 -- Y resulting moment; Inertial (global) coordinates
ServoDyn['BStC1_B1_Mzi']      = False     # (kN-m); Blade StC #1 Blade #1 -- Z resulting moment; Inertial (global) coordinates
ServoDyn['BStC1_B1_Fxl']      = False     # (kN); Blade StC #1 Blade #1 -- X resulting force; Local StC coordinates
ServoDyn['BStC1_B1_Fyl']      = False     # (kN); Blade StC #1 Blade #1 -- Y resulting force; Local StC coordinates
ServoDyn['BStC1_B1_Fzl']      = False     # (kN); Blade StC #1 Blade #1 -- Z resulting force; Local StC coordinates
ServoDyn['BStC1_B1_Mxl']      = False     # (kN-m); Blade StC #1 Blade #1 -- X resulting moment; Local StC coordinates
ServoDyn['BStC1_B1_Myl']      = False     # (kN-m); Blade StC #1 Blade #1 -- Y resulting moment; Local StC coordinates
ServoDyn['BStC1_B1_Mzl']      = False     # (kN-m); Blade StC #1 Blade #1 -- Z resulting moment; Local StC coordinates
ServoDyn['BStC2_B1_XQ']       = False     # (m); Blade StC #2  Blade #1 -- X position (displacement); Relative to rest position in StC reference frame
ServoDyn['BStC2_B1_XQD']      = False     # (m/s); Blade StC #2 Blade #1 -- X velocity; Relative to nacelle in StC reference frame
ServoDyn['BStC2_B1_YQ']       = False     # (m); Blade StC #2 Blade #1 -- Y position (displacement); Relative to rest position in StC reference frame
ServoDyn['BStC2_B1_YQD']      = False     # (m/s); Blade StC #2 Blade #1 -- Y velocity; Relative to nacelle in StC reference frame
ServoDyn['BStC2_B1_ZQ']       = False     # (m); Blade StC #2 Blade #1 -- Z position (displacement); Relative to rest position in StC reference frame
ServoDyn['BStC2_B1_ZQD']      = False     # (m/s); Blade StC #2 Blade #1 -- Z velocity; Relative to nacelle in StC reference frame
ServoDyn['BStC2_B1_Fxi']      = False     # (kN); Blade StC #2 Blade #1 -- X resulting force; Inertial (global) coordinates
ServoDyn['BStC2_B1_Fyi']      = False     # (kN); Blade StC #2 Blade #1 -- Y resulting force; Inertial (global) coordinates
ServoDyn['BStC2_B1_Fzi']      = False     # (kN); Blade StC #2 Blade #1 -- Z resulting force; Inertial (global) coordinates
ServoDyn['BStC2_B1_Mxi']      = False     # (kN-m); Blade StC #2 Blade #1 -- X resulting moment; Inertial (global) coordinates
ServoDyn['BStC2_B1_Myi']      = False     # (kN-m); Blade StC #2 Blade #1 -- Y resulting moment; Inertial (global) coordinates
ServoDyn['BStC2_B1_Mzi']      = False     # (kN-m); Blade StC #2 Blade #1 -- Z resulting moment; Inertial (global) coordinates
ServoDyn['BStC2_B1_Fxl']      = False     # (kN); Blade StC #2 Blade #1 -- X resulting force; Local StC coordinates
ServoDyn['BStC2_B1_Fyl']      = False     # (kN); Blade StC #2 Blade #1 -- Y resulting force; Local StC coordinates
ServoDyn['BStC2_B1_Fzl']      = False     # (kN); Blade StC #2 Blade #1 -- Z resulting force; Local StC coordinates
ServoDyn['BStC2_B1_Mxl']      = False     # (kN-m); Blade StC #2 Blade #1 -- X resulting moment; Local StC coordinates
ServoDyn['BStC2_B1_Myl']      = False     # (kN-m); Blade StC #2 Blade #1 -- Y resulting moment; Local StC coordinates
ServoDyn['BStC2_B1_Mzl']      = False     # (kN-m); Blade StC #2 Blade #1 -- Z resulting moment; Local StC coordinates
ServoDyn['BStC3_B1_XQ']       = False     # (m); Blade StC #3  Blade #1 -- X position (displacement); Relative to rest position in StC reference frame
ServoDyn['BStC3_B1_XQD']      = False     # (m/s); Blade StC #3 Blade #1 -- X velocity; Relative to nacelle in StC reference frame
ServoDyn['BStC3_B1_YQ']       = False     # (m); Blade StC #3 Blade #1 -- Y position (displacement); Relative to rest position in StC reference frame
ServoDyn['BStC3_B1_YQD']      = False     # (m/s); Blade StC #3 Blade #1 -- Y velocity; Relative to nacelle in StC reference frame
ServoDyn['BStC3_B1_ZQ']       = False     # (m); Blade StC #3 Blade #1 -- Z position (displacement); Relative to rest position in StC reference frame
ServoDyn['BStC3_B1_ZQD']      = False     # (m/s); Blade StC #3 Blade #1 -- Z velocity; Relative to nacelle in StC reference frame
ServoDyn['BStC3_B1_Fxi']      = False     # (kN); Blade StC #3 Blade #1 -- X resulting force; Inertial (global) coordinates
ServoDyn['BStC3_B1_Fyi']      = False     # (kN); Blade StC #3 Blade #1 -- Y resulting force; Inertial (global) coordinates
ServoDyn['BStC3_B1_Fzi']      = False     # (kN); Blade StC #3 Blade #1 -- Z resulting force; Inertial (global) coordinates
ServoDyn['BStC3_B1_Mxi']      = False     # (kN-m); Blade StC #3 Blade #1 -- X resulting moment; Inertial (global) coordinates
ServoDyn['BStC3_B1_Myi']      = False     # (kN-m); Blade StC #3 Blade #1 -- Y resulting moment; Inertial (global) coordinates
ServoDyn['BStC3_B1_Mzi']      = False     # (kN-m); Blade StC #3 Blade #1 -- Z resulting moment; Inertial (global) coordinates
ServoDyn['BStC3_B1_Fxl']      = False     # (kN); Blade StC #3 Blade #1 -- X resulting force; Local StC coordinates
ServoDyn['BStC3_B1_Fyl']      = False     # (kN); Blade StC #3 Blade #1 -- Y resulting force; Local StC coordinates
ServoDyn['BStC3_B1_Fzl']      = False     # (kN); Blade StC #3 Blade #1 -- Z resulting force; Local StC coordinates
ServoDyn['BStC3_B1_Mxl']      = False     # (kN-m); Blade StC #3 Blade #1 -- X resulting moment; Local StC coordinates
ServoDyn['BStC3_B1_Myl']      = False     # (kN-m); Blade StC #3 Blade #1 -- Y resulting moment; Local StC coordinates
ServoDyn['BStC3_B1_Mzl']      = False     # (kN-m); Blade StC #3 Blade #1 -- Z resulting moment; Local StC coordinates
ServoDyn['BStC4_B1_XQ']       = False     # (m); Blade StC #4  Blade #1 -- X position (displacement); Relative to rest position in StC reference frame
ServoDyn['BStC4_B1_XQD']      = False     # (m/s); Blade StC #4 Blade #1 -- X velocity; Relative to nacelle in StC reference frame
ServoDyn['BStC4_B1_YQ']       = False     # (m); Blade StC #4 Blade #1 -- Y position (displacement); Relative to rest position in StC reference frame
ServoDyn['BStC4_B1_YQD']      = False     # (m/s); Blade StC #4 Blade #1 -- Y velocity; Relative to nacelle in StC reference frame
ServoDyn['BStC4_B1_ZQ']       = False     # (m); Blade StC #4 Blade #1 -- Z position (displacement); Relative to rest position in StC reference frame
ServoDyn['BStC4_B1_ZQD']      = False     # (m/s); Blade StC #4 Blade #1 -- Z velocity; Relative to nacelle in StC reference frame
ServoDyn['BStC4_B1_Fxi']      = False     # (kN); Blade StC #4 Blade #1 -- X resulting force; Inertial (global) coordinates
ServoDyn['BStC4_B1_Fyi']      = False     # (kN); Blade StC #4 Blade #1 -- Y resulting force; Inertial (global) coordinates
ServoDyn['BStC4_B1_Fzi']      = False     # (kN); Blade StC #4 Blade #1 -- Z resulting force; Inertial (global) coordinates
ServoDyn['BStC4_B1_Mxi']      = False     # (kN-m); Blade StC #4 Blade #1 -- X resulting moment; Inertial (global) coordinates
ServoDyn['BStC4_B1_Myi']      = False     # (kN-m); Blade StC #4 Blade #1 -- Y resulting moment; Inertial (global) coordinates
ServoDyn['BStC4_B1_Mzi']      = False     # (kN-m); Blade StC #4 Blade #1 -- Z resulting moment; Inertial (global) coordinates
ServoDyn['BStC4_B1_Fxl']      = False     # (kN); Blade StC #4 Blade #1 -- X resulting force; Local StC coordinates
ServoDyn['BStC4_B1_Fyl']      = False     # (kN); Blade StC #4 Blade #1 -- Y resulting force; Local StC coordinates
ServoDyn['BStC4_B1_Fzl']      = False     # (kN); Blade StC #4 Blade #1 -- Z resulting force; Local StC coordinates
ServoDyn['BStC4_B1_Mxl']      = False     # (kN-m); Blade StC #4 Blade #1 -- X resulting moment; Local StC coordinates
ServoDyn['BStC4_B1_Myl']      = False     # (kN-m); Blade StC #4 Blade #1 -- Y resulting moment; Local StC coordinates
ServoDyn['BStC4_B1_Mzl']      = False     # (kN-m); Blade StC #4 Blade #1 -- Z resulting moment; Local StC coordinates
ServoDyn['BStC1_B2_XQ']       = False     # (m); Blade StC #1  Blade #2 -- X position (displacement); Relative to rest position in StC reference frame
ServoDyn['BStC1_B2_XQD']      = False     # (m/s); Blade StC #1 Blade #2 -- X velocity; Relative to nacelle in StC reference frame
ServoDyn['BStC1_B2_YQ']       = False     # (m); Blade StC #1 Blade #2 -- Y position (displacement); Relative to rest position in StC reference frame
ServoDyn['BStC1_B2_YQD']      = False     # (m/s); Blade StC #1 Blade #2 -- Y velocity; Relative to nacelle in StC reference frame
ServoDyn['BStC1_B2_ZQ']       = False     # (m); Blade StC #1 Blade #2 -- Z position (displacement); Relative to rest position in StC reference frame
ServoDyn['BStC1_B2_ZQD']      = False     # (m/s); Blade StC #1 Blade #2 -- Z velocity; Relative to nacelle in StC reference frame
ServoDyn['BStC1_B2_Fxi']      = False     # (kN); Blade StC #1 Blade #2 -- X resulting force; Inertial (global) coordinates
ServoDyn['BStC1_B2_Fyi']      = False     # (kN); Blade StC #1 Blade #2 -- Y resulting force; Inertial (global) coordinates
ServoDyn['BStC1_B2_Fzi']      = False     # (kN); Blade StC #1 Blade #2 -- Z resulting force; Inertial (global) coordinates
ServoDyn['BStC1_B2_Mxi']      = False     # (kN-m); Blade StC #1 Blade #2 -- X resulting moment; Inertial (global) coordinates
ServoDyn['BStC1_B2_Myi']      = False     # (kN-m); Blade StC #1 Blade #2 -- Y resulting moment; Inertial (global) coordinates
ServoDyn['BStC1_B2_Mzi']      = False     # (kN-m); Blade StC #1 Blade #2 -- Z resulting moment; Inertial (global) coordinates
ServoDyn['BStC1_B2_Fxl']      = False     # (kN); Blade StC #1 Blade #2 -- X resulting force; Local StC coordinates
ServoDyn['BStC1_B2_Fyl']      = False     # (kN); Blade StC #1 Blade #2 -- Y resulting force; Local StC coordinates
ServoDyn['BStC1_B2_Fzl']      = False     # (kN); Blade StC #1 Blade #2 -- Z resulting force; Local StC coordinates
ServoDyn['BStC1_B2_Mxl']      = False     # (kN-m); Blade StC #1 Blade #2 -- X resulting moment; Local StC coordinates
ServoDyn['BStC1_B2_Myl']      = False     # (kN-m); Blade StC #1 Blade #2 -- Y resulting moment; Local StC coordinates
ServoDyn['BStC1_B2_Mzl']      = False     # (kN-m); Blade StC #1 Blade #2 -- Z resulting moment; Local StC coordinates
ServoDyn['BStC2_B2_XQ']       = False     # (m); Blade StC #2  Blade #2 -- X position (displacement); Relative to rest position in StC reference frame
ServoDyn['BStC2_B2_XQD']      = False     # (m/s); Blade StC #2 Blade #2 -- X velocity; Relative to nacelle in StC reference frame
ServoDyn['BStC2_B2_YQ']       = False     # (m); Blade StC #2 Blade #2 -- Y position (displacement); Relative to rest position in StC reference frame
ServoDyn['BStC2_B2_YQD']      = False     # (m/s); Blade StC #2 Blade #2 -- Y velocity; Relative to nacelle in StC reference frame
ServoDyn['BStC2_B2_ZQ']       = False     # (m); Blade StC #2 Blade #2 -- Z position (displacement); Relative to rest position in StC reference frame
ServoDyn['BStC2_B2_ZQD']      = False     # (m/s); Blade StC #2 Blade #2 -- Z velocity; Relative to nacelle in StC reference frame
ServoDyn['BStC2_B2_Fxi']      = False     # (kN); Blade StC #2 Blade #2 -- X resulting force; Inertial (global) coordinates
ServoDyn['BStC2_B2_Fyi']      = False     # (kN); Blade StC #2 Blade #2 -- Y resulting force; Inertial (global) coordinates
ServoDyn['BStC2_B2_Fzi']      = False     # (kN); Blade StC #2 Blade #2 -- Z resulting force; Inertial (global) coordinates
ServoDyn['BStC2_B2_Mxi']      = False     # (kN-m); Blade StC #2 Blade #2 -- X resulting moment; Inertial (global) coordinates
ServoDyn['BStC2_B2_Myi']      = False     # (kN-m); Blade StC #2 Blade #2 -- Y resulting moment; Inertial (global) coordinates
ServoDyn['BStC2_B2_Mzi']      = False     # (kN-m); Blade StC #2 Blade #2 -- Z resulting moment; Inertial (global) coordinates
ServoDyn['BStC2_B2_Fxl']      = False     # (kN); Blade StC #2 Blade #2 -- X resulting force; Local StC coordinates
ServoDyn['BStC2_B2_Fyl']      = False     # (kN); Blade StC #2 Blade #2 -- Y resulting force; Local StC coordinates
ServoDyn['BStC2_B2_Fzl']      = False     # (kN); Blade StC #2 Blade #2 -- Z resulting force; Local StC coordinates
ServoDyn['BStC2_B2_Mxl']      = False     # (kN-m); Blade StC #2 Blade #2 -- X resulting moment; Local StC coordinates
ServoDyn['BStC2_B2_Myl']      = False     # (kN-m); Blade StC #2 Blade #2 -- Y resulting moment; Local StC coordinates
ServoDyn['BStC2_B2_Mzl']      = False     # (kN-m); Blade StC #2 Blade #2 -- Z resulting moment; Local StC coordinates
ServoDyn['BStC3_B2_XQ']       = False     # (m); Blade StC #3  Blade #2 -- X position (displacement); Relative to rest position in StC reference frame
ServoDyn['BStC3_B2_XQD']      = False     # (m/s); Blade StC #3 Blade #2 -- X velocity; Relative to nacelle in StC reference frame
ServoDyn['BStC3_B2_YQ']       = False     # (m); Blade StC #3 Blade #2 -- Y position (displacement); Relative to rest position in StC reference frame
ServoDyn['BStC3_B2_YQD']      = False     # (m/s); Blade StC #3 Blade #2 -- Y velocity; Relative to nacelle in StC reference frame
ServoDyn['BStC3_B2_ZQ']       = False     # (m); Blade StC #3 Blade #2 -- Z position (displacement); Relative to rest position in StC reference frame
ServoDyn['BStC3_B2_ZQD']      = False     # (m/s); Blade StC #3 Blade #2 -- Z velocity; Relative to nacelle in StC reference frame
ServoDyn['BStC3_B2_Fxi']      = False     # (kN); Blade StC #3 Blade #2 -- X resulting force; Inertial (global) coordinates
ServoDyn['BStC3_B2_Fyi']      = False     # (kN); Blade StC #3 Blade #2 -- Y resulting force; Inertial (global) coordinates
ServoDyn['BStC3_B2_Fzi']      = False     # (kN); Blade StC #3 Blade #2 -- Z resulting force; Inertial (global) coordinates
ServoDyn['BStC3_B2_Mxi']      = False     # (kN-m); Blade StC #3 Blade #2 -- X resulting moment; Inertial (global) coordinates
ServoDyn['BStC3_B2_Myi']      = False     # (kN-m); Blade StC #3 Blade #2 -- Y resulting moment; Inertial (global) coordinates
ServoDyn['BStC3_B2_Mzi']      = False     # (kN-m); Blade StC #3 Blade #2 -- Z resulting moment; Inertial (global) coordinates
ServoDyn['BStC3_B2_Fxl']      = False     # (kN); Blade StC #3 Blade #2 -- X resulting force; Local StC coordinates
ServoDyn['BStC3_B2_Fyl']      = False     # (kN); Blade StC #3 Blade #2 -- Y resulting force; Local StC coordinates
ServoDyn['BStC3_B2_Fzl']      = False     # (kN); Blade StC #3 Blade #2 -- Z resulting force; Local StC coordinates
ServoDyn['BStC3_B2_Mxl']      = False     # (kN-m); Blade StC #3 Blade #2 -- X resulting moment; Local StC coordinates
ServoDyn['BStC3_B2_Myl']      = False     # (kN-m); Blade StC #3 Blade #2 -- Y resulting moment; Local StC coordinates
ServoDyn['BStC3_B2_Mzl']      = False     # (kN-m); Blade StC #3 Blade #2 -- Z resulting moment; Local StC coordinates
ServoDyn['BStC4_B2_XQ']       = False     # (m); Blade StC #4  Blade #2 -- X position (displacement); Relative to rest position in StC reference frame
ServoDyn['BStC4_B2_XQD']      = False     # (m/s); Blade StC #4 Blade #2 -- X velocity; Relative to nacelle in StC reference frame
ServoDyn['BStC4_B2_YQ']       = False     # (m); Blade StC #4 Blade #2 -- Y position (displacement); Relative to rest position in StC reference frame
ServoDyn['BStC4_B2_YQD']      = False     # (m/s); Blade StC #4 Blade #2 -- Y velocity; Relative to nacelle in StC reference frame
ServoDyn['BStC4_B2_ZQ']       = False     # (m); Blade StC #4 Blade #2 -- Z position (displacement); Relative to rest position in StC reference frame
ServoDyn['BStC4_B2_ZQD']      = False     # (m/s); Blade StC #4 Blade #2 -- Z velocity; Relative to nacelle in StC reference frame
ServoDyn['BStC4_B2_Fxi']      = False     # (kN); Blade StC #4 Blade #2 -- X resulting force; Inertial (global) coordinates
ServoDyn['BStC4_B2_Fyi']      = False     # (kN); Blade StC #4 Blade #2 -- Y resulting force; Inertial (global) coordinates
ServoDyn['BStC4_B2_Fzi']      = False     # (kN); Blade StC #4 Blade #2 -- Z resulting force; Inertial (global) coordinates
ServoDyn['BStC4_B2_Mxi']      = False     # (kN-m); Blade StC #4 Blade #2 -- X resulting moment; Inertial (global) coordinates
ServoDyn['BStC4_B2_Myi']      = False     # (kN-m); Blade StC #4 Blade #2 -- Y resulting moment; Inertial (global) coordinates
ServoDyn['BStC4_B2_Mzi']      = False     # (kN-m); Blade StC #4 Blade #2 -- Z resulting moment; Inertial (global) coordinates
ServoDyn['BStC4_B2_Fxl']      = False     # (kN); Blade StC #4 Blade #2 -- X resulting force; Local StC coordinates
ServoDyn['BStC4_B2_Fyl']      = False     # (kN); Blade StC #4 Blade #2 -- Y resulting force; Local StC coordinates
ServoDyn['BStC4_B2_Fzl']      = False     # (kN); Blade StC #4 Blade #2 -- Z resulting force; Local StC coordinates
ServoDyn['BStC4_B2_Mxl']      = False     # (kN-m); Blade StC #4 Blade #2 -- X resulting moment; Local StC coordinates
ServoDyn['BStC4_B2_Myl']      = False     # (kN-m); Blade StC #4 Blade #2 -- Y resulting moment; Local StC coordinates
ServoDyn['BStC4_B2_Mzl']      = False     # (kN-m); Blade StC #4 Blade #2 -- Z resulting moment; Local StC coordinates
ServoDyn['BStC1_B3_XQ']       = False     # (m); Blade StC #1  Blade #3 -- X position (displacement); Relative to rest position in StC reference frame
ServoDyn['BStC1_B3_XQD']      = False     # (m/s); Blade StC #1 Blade #3 -- X velocity; Relative to nacelle in StC reference frame
ServoDyn['BStC1_B3_YQ']       = False     # (m); Blade StC #1 Blade #3 -- Y position (displacement); Relative to rest position in StC reference frame
ServoDyn['BStC1_B3_YQD']      = False     # (m/s); Blade StC #1 Blade #3 -- Y velocity; Relative to nacelle in StC reference frame
ServoDyn['BStC1_B3_ZQ']       = False     # (m); Blade StC #1 Blade #3 -- Z position (displacement); Relative to rest position in StC reference frame
ServoDyn['BStC1_B3_ZQD']      = False     # (m/s); Blade StC #1 Blade #3 -- Z velocity; Relative to nacelle in StC reference frame
ServoDyn['BStC1_B3_Fxi']      = False     # (kN); Blade StC #1 Blade #3 -- X resulting force; Inertial (global) coordinates
ServoDyn['BStC1_B3_Fyi']      = False     # (kN); Blade StC #1 Blade #3 -- Y resulting force; Inertial (global) coordinates
ServoDyn['BStC1_B3_Fzi']      = False     # (kN); Blade StC #1 Blade #3 -- Z resulting force; Inertial (global) coordinates
ServoDyn['BStC1_B3_Mxi']      = False     # (kN-m); Blade StC #1 Blade #3 -- X resulting moment; Inertial (global) coordinates
ServoDyn['BStC1_B3_Myi']      = False     # (kN-m); Blade StC #1 Blade #3 -- Y resulting moment; Inertial (global) coordinates
ServoDyn['BStC1_B3_Mzi']      = False     # (kN-m); Blade StC #1 Blade #3 -- Z resulting moment; Inertial (global) coordinates
ServoDyn['BStC1_B3_Fxl']      = False     # (kN); Blade StC #1 Blade #3 -- X resulting force; Local StC coordinates
ServoDyn['BStC1_B3_Fyl']      = False     # (kN); Blade StC #1 Blade #3 -- Y resulting force; Local StC coordinates
ServoDyn['BStC1_B3_Fzl']      = False     # (kN); Blade StC #1 Blade #3 -- Z resulting force; Local StC coordinates
ServoDyn['BStC1_B3_Mxl']      = False     # (kN-m); Blade StC #1 Blade #3 -- X resulting moment; Local StC coordinates
ServoDyn['BStC1_B3_Myl']      = False     # (kN-m); Blade StC #1 Blade #3 -- Y resulting moment; Local StC coordinates
ServoDyn['BStC1_B3_Mzl']      = False     # (kN-m); Blade StC #1 Blade #3 -- Z resulting moment; Local StC coordinates
ServoDyn['BStC2_B3_XQ']       = False     # (m); Blade StC #2  Blade #3 -- X position (displacement); Relative to rest position in StC reference frame
ServoDyn['BStC2_B3_XQD']      = False     # (m/s); Blade StC #2 Blade #3 -- X velocity; Relative to nacelle in StC reference frame
ServoDyn['BStC2_B3_YQ']       = False     # (m); Blade StC #2 Blade #3 -- Y position (displacement); Relative to rest position in StC reference frame
ServoDyn['BStC2_B3_YQD']      = False     # (m/s); Blade StC #2 Blade #3 -- Y velocity; Relative to nacelle in StC reference frame
ServoDyn['BStC2_B3_ZQ']       = False     # (m); Blade StC #2 Blade #3 -- Z position (displacement); Relative to rest position in StC reference frame
ServoDyn['BStC2_B3_ZQD']      = False     # (m/s); Blade StC #2 Blade #3 -- Z velocity; Relative to nacelle in StC reference frame
ServoDyn['BStC2_B3_Fxi']      = False     # (kN); Blade StC #2 Blade #3 -- X resulting force; Inertial (global) coordinates
ServoDyn['BStC2_B3_Fyi']      = False     # (kN); Blade StC #2 Blade #3 -- Y resulting force; Inertial (global) coordinates
ServoDyn['BStC2_B3_Fzi']      = False     # (kN); Blade StC #2 Blade #3 -- Z resulting force; Inertial (global) coordinates
ServoDyn['BStC2_B3_Mxi']      = False     # (kN-m); Blade StC #2 Blade #3 -- X resulting moment; Inertial (global) coordinates
ServoDyn['BStC2_B3_Myi']      = False     # (kN-m); Blade StC #2 Blade #3 -- Y resulting moment; Inertial (global) coordinates
ServoDyn['BStC2_B3_Mzi']      = False     # (kN-m); Blade StC #2 Blade #3 -- Z resulting moment; Inertial (global) coordinates
ServoDyn['BStC2_B3_Fxl']      = False     # (kN); Blade StC #2 Blade #3 -- X resulting force; Local StC coordinates
ServoDyn['BStC2_B3_Fyl']      = False     # (kN); Blade StC #2 Blade #3 -- Y resulting force; Local StC coordinates
ServoDyn['BStC2_B3_Fzl']      = False     # (kN); Blade StC #2 Blade #3 -- Z resulting force; Local StC coordinates
ServoDyn['BStC2_B3_Mxl']      = False     # (kN-m); Blade StC #2 Blade #3 -- X resulting moment; Local StC coordinates
ServoDyn['BStC2_B3_Myl']      = False     # (kN-m); Blade StC #2 Blade #3 -- Y resulting moment; Local StC coordinates
ServoDyn['BStC2_B3_Mzl']      = False     # (kN-m); Blade StC #2 Blade #3 -- Z resulting moment; Local StC coordinates
ServoDyn['BStC3_B3_XQ']       = False     # (m); Blade StC #3  Blade #3 -- X position (displacement); Relative to rest position in StC reference frame
ServoDyn['BStC3_B3_XQD']      = False     # (m/s); Blade StC #3 Blade #3 -- X velocity; Relative to nacelle in StC reference frame
ServoDyn['BStC3_B3_YQ']       = False     # (m); Blade StC #3 Blade #3 -- Y position (displacement); Relative to rest position in StC reference frame
ServoDyn['BStC3_B3_YQD']      = False     # (m/s); Blade StC #3 Blade #3 -- Y velocity; Relative to nacelle in StC reference frame
ServoDyn['BStC3_B3_ZQ']       = False     # (m); Blade StC #3 Blade #3 -- Z position (displacement); Relative to rest position in StC reference frame
ServoDyn['BStC3_B3_ZQD']      = False     # (m/s); Blade StC #3 Blade #3 -- Z velocity; Relative to nacelle in StC reference frame
ServoDyn['BStC3_B3_Fxi']      = False     # (kN); Blade StC #3 Blade #3 -- X resulting force; Inertial (global) coordinates
ServoDyn['BStC3_B3_Fyi']      = False     # (kN); Blade StC #3 Blade #3 -- Y resulting force; Inertial (global) coordinates
ServoDyn['BStC3_B3_Fzi']      = False     # (kN); Blade StC #3 Blade #3 -- Z resulting force; Inertial (global) coordinates
ServoDyn['BStC3_B3_Mxi']      = False     # (kN-m); Blade StC #3 Blade #3 -- X resulting moment; Inertial (global) coordinates
ServoDyn['BStC3_B3_Myi']      = False     # (kN-m); Blade StC #3 Blade #3 -- Y resulting moment; Inertial (global) coordinates
ServoDyn['BStC3_B3_Mzi']      = False     # (kN-m); Blade StC #3 Blade #3 -- Z resulting moment; Inertial (global) coordinates
ServoDyn['BStC3_B3_Fxl']      = False     # (kN); Blade StC #3 Blade #3 -- X resulting force; Local StC coordinates
ServoDyn['BStC3_B3_Fyl']      = False     # (kN); Blade StC #3 Blade #3 -- Y resulting force; Local StC coordinates
ServoDyn['BStC3_B3_Fzl']      = False     # (kN); Blade StC #3 Blade #3 -- Z resulting force; Local StC coordinates
ServoDyn['BStC3_B3_Mxl']      = False     # (kN-m); Blade StC #3 Blade #3 -- X resulting moment; Local StC coordinates
ServoDyn['BStC3_B3_Myl']      = False     # (kN-m); Blade StC #3 Blade #3 -- Y resulting moment; Local StC coordinates
ServoDyn['BStC3_B3_Mzl']      = False     # (kN-m); Blade StC #3 Blade #3 -- Z resulting moment; Local StC coordinates
ServoDyn['BStC4_B3_XQ']       = False     # (m); Blade StC #4  Blade #3 -- X position (displacement); Relative to rest position in StC reference frame
ServoDyn['BStC4_B3_XQD']      = False     # (m/s); Blade StC #4 Blade #3 -- X velocity; Relative to nacelle in StC reference frame
ServoDyn['BStC4_B3_YQ']       = False     # (m); Blade StC #4 Blade #3 -- Y position (displacement); Relative to rest position in StC reference frame
ServoDyn['BStC4_B3_YQD']      = False     # (m/s); Blade StC #4 Blade #3 -- Y velocity; Relative to nacelle in StC reference frame
ServoDyn['BStC4_B3_ZQ']       = False     # (m); Blade StC #4 Blade #3 -- Z position (displacement); Relative to rest position in StC reference frame
ServoDyn['BStC4_B3_ZQD']      = False     # (m/s); Blade StC #4 Blade #3 -- Z velocity; Relative to nacelle in StC reference frame
ServoDyn['BStC4_B3_Fxi']      = False     # (kN); Blade StC #4 Blade #3 -- X resulting force; Inertial (global) coordinates
ServoDyn['BStC4_B3_Fyi']      = False     # (kN); Blade StC #4 Blade #3 -- Y resulting force; Inertial (global) coordinates
ServoDyn['BStC4_B3_Fzi']      = False     # (kN); Blade StC #4 Blade #3 -- Z resulting force; Inertial (global) coordinates
ServoDyn['BStC4_B3_Mxi']      = False     # (kN-m); Blade StC #4 Blade #3 -- X resulting moment; Inertial (global) coordinates
ServoDyn['BStC4_B3_Myi']      = False     # (kN-m); Blade StC #4 Blade #3 -- Y resulting moment; Inertial (global) coordinates
ServoDyn['BStC4_B3_Mzi']      = False     # (kN-m); Blade StC #4 Blade #3 -- Z resulting moment; Inertial (global) coordinates
ServoDyn['BStC4_B3_Fxl']      = False     # (kN); Blade StC #4 Blade #3 -- X resulting force; Local StC coordinates
ServoDyn['BStC4_B3_Fyl']      = False     # (kN); Blade StC #4 Blade #3 -- Y resulting force; Local StC coordinates
ServoDyn['BStC4_B3_Fzl']      = False     # (kN); Blade StC #4 Blade #3 -- Z resulting force; Local StC coordinates
ServoDyn['BStC4_B3_Mxl']      = False     # (kN-m); Blade StC #4 Blade #3 -- X resulting moment; Local StC coordinates
ServoDyn['BStC4_B3_Myl']      = False     # (kN-m); Blade StC #4 Blade #3 -- Y resulting moment; Local StC coordinates
ServoDyn['BStC4_B3_Mzl']      = False     # (kN-m); Blade StC #4 Blade #3 -- Z resulting moment; Local StC coordinates
ServoDyn['BStC1_B4_XQ']       = False     # (m); Blade StC #1  Blade #4 -- X position (displacement); Relative to rest position in StC reference frame
ServoDyn['BStC1_B4_XQD']      = False     # (m/s); Blade StC #1 Blade #4 -- X velocity; Relative to nacelle in StC reference frame
ServoDyn['BStC1_B4_YQ']       = False     # (m); Blade StC #1 Blade #4 -- Y position (displacement); Relative to rest position in StC reference frame
ServoDyn['BStC1_B4_YQD']      = False     # (m/s); Blade StC #1 Blade #4 -- Y velocity; Relative to nacelle in StC reference frame
ServoDyn['BStC1_B4_ZQ']       = False     # (m); Blade StC #1 Blade #4 -- Z position (displacement); Relative to rest position in StC reference frame
ServoDyn['BStC1_B4_ZQD']      = False     # (m/s); Blade StC #1 Blade #4 -- Z velocity; Relative to nacelle in StC reference frame
ServoDyn['BStC1_B4_Fxi']      = False     # (kN); Blade StC #1 Blade #4 -- X resulting force; Inertial (global) coordinates
ServoDyn['BStC1_B4_Fyi']      = False     # (kN); Blade StC #1 Blade #4 -- Y resulting force; Inertial (global) coordinates
ServoDyn['BStC1_B4_Fzi']      = False     # (kN); Blade StC #1 Blade #4 -- Z resulting force; Inertial (global) coordinates
ServoDyn['BStC1_B4_Mxi']      = False     # (kN-m); Blade StC #1 Blade #4 -- X resulting moment; Inertial (global) coordinates
ServoDyn['BStC1_B4_Myi']      = False     # (kN-m); Blade StC #1 Blade #4 -- Y resulting moment; Inertial (global) coordinates
ServoDyn['BStC1_B4_Mzi']      = False     # (kN-m); Blade StC #1 Blade #4 -- Z resulting moment; Inertial (global) coordinates
ServoDyn['BStC1_B4_Fxl']      = False     # (kN); Blade StC #1 Blade #4 -- X resulting force; Local StC coordinates
ServoDyn['BStC1_B4_Fyl']      = False     # (kN); Blade StC #1 Blade #4 -- Y resulting force; Local StC coordinates
ServoDyn['BStC1_B4_Fzl']      = False     # (kN); Blade StC #1 Blade #4 -- Z resulting force; Local StC coordinates
ServoDyn['BStC1_B4_Mxl']      = False     # (kN-m); Blade StC #1 Blade #4 -- X resulting moment; Local StC coordinates
ServoDyn['BStC1_B4_Myl']      = False     # (kN-m); Blade StC #1 Blade #4 -- Y resulting moment; Local StC coordinates
ServoDyn['BStC1_B4_Mzl']      = False     # (kN-m); Blade StC #1 Blade #4 -- Z resulting moment; Local StC coordinates
ServoDyn['BStC2_B4_XQ']       = False     # (m); Blade StC #2  Blade #4 -- X position (displacement); Relative to rest position in StC reference frame
ServoDyn['BStC2_B4_XQD']      = False     # (m/s); Blade StC #2 Blade #4 -- X velocity; Relative to nacelle in StC reference frame
ServoDyn['BStC2_B4_YQ']       = False     # (m); Blade StC #2 Blade #4 -- Y position (displacement); Relative to rest position in StC reference frame
ServoDyn['BStC2_B4_YQD']      = False     # (m/s); Blade StC #2 Blade #4 -- Y velocity; Relative to nacelle in StC reference frame
ServoDyn['BStC2_B4_ZQ']       = False     # (m); Blade StC #2 Blade #4 -- Z position (displacement); Relative to rest position in StC reference frame
ServoDyn['BStC2_B4_ZQD']      = False     # (m/s); Blade StC #2 Blade #4 -- Z velocity; Relative to nacelle in StC reference frame
ServoDyn['BStC2_B4_Fxi']      = False     # (kN); Blade StC #2 Blade #4 -- X resulting force; Inertial (global) coordinates
ServoDyn['BStC2_B4_Fyi']      = False     # (kN); Blade StC #2 Blade #4 -- Y resulting force; Inertial (global) coordinates
ServoDyn['BStC2_B4_Fzi']      = False     # (kN); Blade StC #2 Blade #4 -- Z resulting force; Inertial (global) coordinates
ServoDyn['BStC2_B4_Mxi']      = False     # (kN-m); Blade StC #2 Blade #4 -- X resulting moment; Inertial (global) coordinates
ServoDyn['BStC2_B4_Myi']      = False     # (kN-m); Blade StC #2 Blade #4 -- Y resulting moment; Inertial (global) coordinates
ServoDyn['BStC2_B4_Mzi']      = False     # (kN-m); Blade StC #2 Blade #4 -- Z resulting moment; Inertial (global) coordinates
ServoDyn['BStC2_B4_Fxl']      = False     # (kN); Blade StC #2 Blade #4 -- X resulting force; Local StC coordinates
ServoDyn['BStC2_B4_Fyl']      = False     # (kN); Blade StC #2 Blade #4 -- Y resulting force; Local StC coordinates
ServoDyn['BStC2_B4_Fzl']      = False     # (kN); Blade StC #2 Blade #4 -- Z resulting force; Local StC coordinates
ServoDyn['BStC2_B4_Mxl']      = False     # (kN-m); Blade StC #2 Blade #4 -- X resulting moment; Local StC coordinates
ServoDyn['BStC2_B4_Myl']      = False     # (kN-m); Blade StC #2 Blade #4 -- Y resulting moment; Local StC coordinates
ServoDyn['BStC2_B4_Mzl']      = False     # (kN-m); Blade StC #2 Blade #4 -- Z resulting moment; Local StC coordinates
ServoDyn['BStC3_B4_XQ']       = False     # (m); Blade StC #3  Blade #4 -- X position (displacement); Relative to rest position in StC reference frame
ServoDyn['BStC3_B4_XQD']      = False     # (m/s); Blade StC #3 Blade #4 -- X velocity; Relative to nacelle in StC reference frame
ServoDyn['BStC3_B4_YQ']       = False     # (m); Blade StC #3 Blade #4 -- Y position (displacement); Relative to rest position in StC reference frame
ServoDyn['BStC3_B4_YQD']      = False     # (m/s); Blade StC #3 Blade #4 -- Y velocity; Relative to nacelle in StC reference frame
ServoDyn['BStC3_B4_ZQ']       = False     # (m); Blade StC #3 Blade #4 -- Z position (displacement); Relative to rest position in StC reference frame
ServoDyn['BStC3_B4_ZQD']      = False     # (m/s); Blade StC #3 Blade #4 -- Z velocity; Relative to nacelle in StC reference frame
ServoDyn['BStC3_B4_Fxi']      = False     # (kN); Blade StC #3 Blade #4 -- X resulting force; Inertial (global) coordinates
ServoDyn['BStC3_B4_Fyi']      = False     # (kN); Blade StC #3 Blade #4 -- Y resulting force; Inertial (global) coordinates
ServoDyn['BStC3_B4_Fzi']      = False     # (kN); Blade StC #3 Blade #4 -- Z resulting force; Inertial (global) coordinates
ServoDyn['BStC3_B4_Mxi']      = False     # (kN-m); Blade StC #3 Blade #4 -- X resulting moment; Inertial (global) coordinates
ServoDyn['BStC3_B4_Myi']      = False     # (kN-m); Blade StC #3 Blade #4 -- Y resulting moment; Inertial (global) coordinates
ServoDyn['BStC3_B4_Mzi']      = False     # (kN-m); Blade StC #3 Blade #4 -- Z resulting moment; Inertial (global) coordinates
ServoDyn['BStC3_B4_Fxl']      = False     # (kN); Blade StC #3 Blade #4 -- X resulting force; Local StC coordinates
ServoDyn['BStC3_B4_Fyl']      = False     # (kN); Blade StC #3 Blade #4 -- Y resulting force; Local StC coordinates
ServoDyn['BStC3_B4_Fzl']      = False     # (kN); Blade StC #3 Blade #4 -- Z resulting force; Local StC coordinates
ServoDyn['BStC3_B4_Mxl']      = False     # (kN-m); Blade StC #3 Blade #4 -- X resulting moment; Local StC coordinates
ServoDyn['BStC3_B4_Myl']      = False     # (kN-m); Blade StC #3 Blade #4 -- Y resulting moment; Local StC coordinates
ServoDyn['BStC3_B4_Mzl']      = False     # (kN-m); Blade StC #3 Blade #4 -- Z resulting moment; Local StC coordinates
ServoDyn['BStC4_B4_XQ']       = False     # (m); Blade StC #4  Blade #4 -- X position (displacement); Relative to rest position in StC reference frame
ServoDyn['BStC4_B4_XQD']      = False     # (m/s); Blade StC #4 Blade #4 -- X velocity; Relative to nacelle in StC reference frame
ServoDyn['BStC4_B4_YQ']       = False     # (m); Blade StC #4 Blade #4 -- Y position (displacement); Relative to rest position in StC reference frame
ServoDyn['BStC4_B4_YQD']      = False     # (m/s); Blade StC #4 Blade #4 -- Y velocity; Relative to nacelle in StC reference frame
ServoDyn['BStC4_B4_ZQ']       = False     # (m); Blade StC #4 Blade #4 -- Z position (displacement); Relative to rest position in StC reference frame
ServoDyn['BStC4_B4_ZQD']      = False     # (m/s); Blade StC #4 Blade #4 -- Z velocity; Relative to nacelle in StC reference frame
ServoDyn['BStC4_B4_Fxi']      = False     # (kN); Blade StC #4 Blade #4 -- X resulting force; Inertial (global) coordinates
ServoDyn['BStC4_B4_Fyi']      = False     # (kN); Blade StC #4 Blade #4 -- Y resulting force; Inertial (global) coordinates
ServoDyn['BStC4_B4_Fzi']      = False     # (kN); Blade StC #4 Blade #4 -- Z resulting force; Inertial (global) coordinates
ServoDyn['BStC4_B4_Mxi']      = False     # (kN-m); Blade StC #4 Blade #4 -- X resulting moment; Inertial (global) coordinates
ServoDyn['BStC4_B4_Myi']      = False     # (kN-m); Blade StC #4 Blade #4 -- Y resulting moment; Inertial (global) coordinates
ServoDyn['BStC4_B4_Mzi']      = False     # (kN-m); Blade StC #4 Blade #4 -- Z resulting moment; Inertial (global) coordinates
ServoDyn['BStC4_B4_Fxl']      = False     # (kN); Blade StC #4 Blade #4 -- X resulting force; Local StC coordinates
ServoDyn['BStC4_B4_Fyl']      = False     # (kN); Blade StC #4 Blade #4 -- Y resulting force; Local StC coordinates
ServoDyn['BStC4_B4_Fzl']      = False     # (kN); Blade StC #4 Blade #4 -- Z resulting force; Local StC coordinates
ServoDyn['BStC4_B4_Mxl']      = False     # (kN-m); Blade StC #4 Blade #4 -- X resulting moment; Local StC coordinates
ServoDyn['BStC4_B4_Myl']      = False     # (kN-m); Blade StC #4 Blade #4 -- Y resulting moment; Local StC coordinates
ServoDyn['BStC4_B4_Mzl']      = False     # (kN-m); Blade StC #4 Blade #4 -- Z resulting moment; Local StC coordinates

# Substructure  Structural Control  (StC)
ServoDyn['SStC1_XQ']          = False     # (m); Substructure StC #1  -- X position (displacement); Relative to rest position in StC reference frame
ServoDyn['SStC1_XQD']         = False     # (m/s); Substructure StC #1 -- X velocity; Relative to nacelle in StC reference frame
ServoDyn['SStC1_YQ']          = False     # (m); Substructure StC #1 -- Y position (displacement); Relative to rest position in StC reference frame
ServoDyn['SStC1_YQD']         = False     # (m/s); Substructure StC #1 -- Y velocity; Relative to nacelle in StC reference frame
ServoDyn['SStC1_ZQ']          = False     # (m); Substructure StC #1 -- Z position (displacement); Relative to rest position in StC reference frame
ServoDyn['SStC1_ZQD']         = False     # (m/s); Substructure StC #1 -- Z velocity; Relative to nacelle in StC reference frame
ServoDyn['SStC1_Fxi']         = False     # (kN); Substructure StC #1 -- X resulting force; Inertial (global) coordinates
ServoDyn['SStC1_Fyi']         = False     # (kN); Substructure StC #1 -- Y resulting force; Inertial (global) coordinates
ServoDyn['SStC1_Fzi']         = False     # (kN); Substructure StC #1 -- Z resulting force; Inertial (global) coordinates
ServoDyn['SStC1_Mxi']         = False     # (kN-m); Substructure StC #1 -- X resulting moment; Inertial (global) coordinates
ServoDyn['SStC1_Myi']         = False     # (kN-m); Substructure StC #1 -- Y resulting moment; Inertial (global) coordinates
ServoDyn['SStC1_Mzi']         = False     # (kN-m); Substructure StC #1 -- Z resulting moment; Inertial (global) coordinates
ServoDyn['SStC1_Fxl']         = False     # (kN); Substructure StC #1 -- X resulting force; Local StC coordinates
ServoDyn['SStC1_Fyl']         = False     # (kN); Substructure StC #1 -- Y resulting force; Local StC coordinates
ServoDyn['SStC1_Fzl']         = False     # (kN); Substructure StC #1 -- Z resulting force; Local StC coordinates
ServoDyn['SStC1_Mxl']         = False     # (kN-m); Substructure StC #1 -- X resulting moment; Local StC coordinates
ServoDyn['SStC1_Myl']         = False     # (kN-m); Substructure StC #1 -- Y resulting moment; Local StC coordinates
ServoDyn['SStC1_Mzl']         = False     # (kN-m); Substructure StC #1 -- Z resulting moment; Local StC coordinates
ServoDyn['SStC2_XQ']          = False     # (m); Substructure StC #2  -- X position (displacement); Relative to rest position in StC reference frame
ServoDyn['SStC2_XQD']         = False     # (m/s); Substructure StC #2 -- X velocity; Relative to nacelle in StC reference frame
ServoDyn['SStC2_YQ']          = False     # (m); Substructure StC #2 -- Y position (displacement); Relative to rest position in StC reference frame
ServoDyn['SStC2_YQD']         = False     # (m/s); Substructure StC #2 -- Y velocity; Relative to nacelle in StC reference frame
ServoDyn['SStC2_ZQ']          = False     # (m); Substructure StC #2 -- Z position (displacement); Relative to rest position in StC reference frame
ServoDyn['SStC2_ZQD']         = False     # (m/s); Substructure StC #2 -- Z velocity; Relative to nacelle in StC reference frame
ServoDyn['SStC2_Fxi']         = False     # (kN); Substructure StC #2 -- X resulting force; Inertial (global) coordinates
ServoDyn['SStC2_Fyi']         = False     # (kN); Substructure StC #2 -- Y resulting force; Inertial (global) coordinates
ServoDyn['SStC2_Fzi']         = False     # (kN); Substructure StC #2 -- Z resulting force; Inertial (global) coordinates
ServoDyn['SStC2_Mxi']         = False     # (kN-m); Substructure StC #2 -- X resulting moment; Inertial (global) coordinates
ServoDyn['SStC2_Myi']         = False     # (kN-m); Substructure StC #2 -- Y resulting moment; Inertial (global) coordinates
ServoDyn['SStC2_Mzi']         = False     # (kN-m); Substructure StC #2 -- Z resulting moment; Inertial (global) coordinates
ServoDyn['SStC2_Fxl']         = False     # (kN); Substructure StC #2 -- X resulting force; Local StC coordinates
ServoDyn['SStC2_Fyl']         = False     # (kN); Substructure StC #2 -- Y resulting force; Local StC coordinates
ServoDyn['SStC2_Fzl']         = False     # (kN); Substructure StC #2 -- Z resulting force; Local StC coordinates
ServoDyn['SStC2_Mxl']         = False     # (kN-m); Substructure StC #2 -- X resulting moment; Local StC coordinates
ServoDyn['SStC2_Myl']         = False     # (kN-m); Substructure StC #2 -- Y resulting moment; Local StC coordinates
ServoDyn['SStC2_Mzl']         = False     # (kN-m); Substructure StC #2 -- Z resulting moment; Local StC coordinates
ServoDyn['SStC3_XQ']          = False     # (m); Substructure StC #3  -- X position (displacement); Relative to rest position in StC reference frame
ServoDyn['SStC3_XQD']         = False     # (m/s); Substructure StC #3 -- X velocity; Relative to nacelle in StC reference frame
ServoDyn['SStC3_YQ']          = False     # (m); Substructure StC #3 -- Y position (displacement); Relative to rest position in StC reference frame
ServoDyn['SStC3_YQD']         = False     # (m/s); Substructure StC #3 -- Y velocity; Relative to nacelle in StC reference frame
ServoDyn['SStC3_ZQ']          = False     # (m); Substructure StC #3 -- Z position (displacement); Relative to rest position in StC reference frame
ServoDyn['SStC3_ZQD']         = False     # (m/s); Substructure StC #3 -- Z velocity; Relative to nacelle in StC reference frame
ServoDyn['SStC3_Fxi']         = False     # (kN); Substructure StC #3 -- X resulting force; Inertial (global) coordinates
ServoDyn['SStC3_Fyi']         = False     # (kN); Substructure StC #3 -- Y resulting force; Inertial (global) coordinates
ServoDyn['SStC3_Fzi']         = False     # (kN); Substructure StC #3 -- Z resulting force; Inertial (global) coordinates
ServoDyn['SStC3_Mxi']         = False     # (kN-m); Substructure StC #3 -- X resulting moment; Inertial (global) coordinates
ServoDyn['SStC3_Myi']         = False     # (kN-m); Substructure StC #3 -- Y resulting moment; Inertial (global) coordinates
ServoDyn['SStC3_Mzi']         = False     # (kN-m); Substructure StC #3 -- Z resulting moment; Inertial (global) coordinates
ServoDyn['SStC3_Fxl']         = False     # (kN); Substructure StC #3 -- X resulting force; Local StC coordinates
ServoDyn['SStC3_Fyl']         = False     # (kN); Substructure StC #3 -- Y resulting force; Local StC coordinates
ServoDyn['SStC3_Fzl']         = False     # (kN); Substructure StC #3 -- Z resulting force; Local StC coordinates
ServoDyn['SStC3_Mxl']         = False     # (kN-m); Substructure StC #3 -- X resulting moment; Local StC coordinates
ServoDyn['SStC3_Myl']         = False     # (kN-m); Substructure StC #3 -- Y resulting moment; Local StC coordinates
ServoDyn['SStC3_Mzl']         = False     # (kN-m); Substructure StC #3 -- Z resulting moment; Local StC coordinates
ServoDyn['SStC4_XQ']          = False     # (m); Substructure StC #4  -- X position (displacement); Relative to rest position in StC reference frame
ServoDyn['SStC4_XQD']         = False     # (m/s); Substructure StC #4 -- X velocity; Relative to nacelle in StC reference frame
ServoDyn['SStC4_YQ']          = False     # (m); Substructure StC #4 -- Y position (displacement); Relative to rest position in StC reference frame
ServoDyn['SStC4_YQD']         = False     # (m/s); Substructure StC #4 -- Y velocity; Relative to nacelle in StC reference frame
ServoDyn['SStC4_ZQ']          = False     # (m); Substructure StC #4 -- Z position (displacement); Relative to rest position in StC reference frame
ServoDyn['SStC4_ZQD']         = False     # (m/s); Substructure StC #4 -- Z velocity; Relative to nacelle in StC reference frame
ServoDyn['SStC4_Fxi']         = False     # (kN); Substructure StC #4 -- X resulting force; Inertial (global) coordinates
ServoDyn['SStC4_Fyi']         = False     # (kN); Substructure StC #4 -- Y resulting force; Inertial (global) coordinates
ServoDyn['SStC4_Fzi']         = False     # (kN); Substructure StC #4 -- Z resulting force; Inertial (global) coordinates
ServoDyn['SStC4_Mxi']         = False     # (kN-m); Substructure StC #4 -- X resulting moment; Inertial (global) coordinates
ServoDyn['SStC4_Myi']         = False     # (kN-m); Substructure StC #4 -- Y resulting moment; Inertial (global) coordinates
ServoDyn['SStC4_Mzi']         = False     # (kN-m); Substructure StC #4 -- Z resulting moment; Inertial (global) coordinates
ServoDyn['SStC4_Fxl']         = False     # (kN); Substructure StC #4 -- X resulting force; Local StC coordinates
ServoDyn['SStC4_Fyl']         = False     # (kN); Substructure StC #4 -- Y resulting force; Local StC coordinates
ServoDyn['SStC4_Fzl']         = False     # (kN); Substructure StC #4 -- Z resulting force; Local StC coordinates
ServoDyn['SStC4_Mxl']         = False     # (kN-m); Substructure StC #4 -- X resulting moment; Local StC coordinates
ServoDyn['SStC4_Myl']         = False     # (kN-m); Substructure StC #4 -- Y resulting moment; Local StC coordinates
ServoDyn['SStC4_Mzl']         = False     # (kN-m); Substructure StC #4 -- Z resulting moment; Local StC coordinates


""" HydroDyn """
HydroDyn = {}

# Integrated Hydrodynamic Loads at (0,0,0)
HydroDyn['HydroFxi']          = False     # (N); Total integrated hydrodynamic load along the global x-direction from both potential flow and strip theory at (0,0,0); 
HydroDyn['HydroFyi']          = False     # (N); Total integrated hydrodynamic load along the global y-direction from both potential flow and strip theory at (0,0,0); 
HydroDyn['HydroFzi']          = False     # (N); Total integrated hydrodynamic load along the global z-direction from both potential flow and strip theory at (0,0,0); 
HydroDyn['HydroMxi']          = False     # (N-m); Total integrated hydrodynamic moment about the global x-axis from both potential flow and strip theory at (0,0,0); 
HydroDyn['HydroMyi']          = False     # (N-m); Total integrated hydrodynamic moment about the global y-axis from both potential flow and strip theory at (0,0,0); 
HydroDyn['HydroMzi']          = False     # (N-m); Total integrated hydrodynamic moment about the global z-axis from both potential flow and strip theory at (0,0,0); 

# PRP Body Kinematics
HydroDyn['PRPSurge']          = False     # (m); Displacement of the PRP (principal reference point) along the global x-axis; 
HydroDyn['PRPSway']           = False     # (m); Displacement of the PRP (principal reference point) along the global y-axis; 
HydroDyn['PRPHeave']          = False     # (m); Displacement of the PRP (principal reference point) along the global z-axis; 
HydroDyn['PRPRoll']           = False     # (rad); Rotation of the PRP (principal reference point) about the global x-axis at the PRP; 
HydroDyn['PRPPitch']          = False     # (rad); Rotation of the PRP (principal reference point) about the global y-axis at the PRP; 
HydroDyn['PRPYaw']            = False     # (rad); Rotation of the PRP (principal reference point) about the global z-axis at the PRP; 
HydroDyn['PRPTVxi']           = False     # (m/s); Translational velocity of the PRP (principal reference point) along the global x-axis; 
HydroDyn['PRPTVyi']           = False     # (m/s); Translational velocity of the PRP (principal reference point) along the global y-axis; 
HydroDyn['PRPTVzi']           = False     # (m/s); Translational velocity of the PRP (principal reference point) along the global z-axis; 
HydroDyn['PRPRVxi']           = False     # (rad/s); Rotation velocity of the PRP (principal reference point) about the global x-axis at the PRP; 
HydroDyn['PRPRVyi']           = False     # (rad/s); Rotation velocity of the PRP (principal reference point) about the global y-axis at the PRP; 
HydroDyn['PRPRVzi']           = False     # (rad/s); Rotation velocity of the PRP (principal reference point) about the global z-axis at the PRP; 
HydroDyn['PRPTAxi']           = False     # (m/s^2); Translational acceleration of the PRP (principal reference point) along the global x-axis; 
HydroDyn['PRPTAyi']           = False     # (m/s^2); Translational acceleration of the PRP (principal reference point) along the global y-axis; 
HydroDyn['PRPTAzi']           = False     # (m/s^2); Translational acceleration of the PRP (principal reference point) along the global z-axis; 
HydroDyn['PRPRAxi']           = False     # (rad/s^2); Rotation acceleration of the PRP (principal reference point) about the global x-axis at the PRP; 
HydroDyn['PRPRAyi']           = False     # (rad/s^2); Rotation acceleration of the PRP (principal reference point) about the global y-axis at the PRP; 
HydroDyn['PRPRAzi']           = False     # (rad/s^2); Rotation acceleration of the PRP (principal reference point) about the global z-axis at the PRP; 

# WAMIT Body Kinematics
HydroDyn['B1Surge']           = False     # (m); Displacement of the 1st WAMIT body along the global x-axis; 
HydroDyn['B1Sway']            = False     # (m); Displacement of the 1st WAMIT body along the global y-axis; 
HydroDyn['B1Heave']           = False     # (m); Displacement of the 1st WAMIT body along the global z-axis; 
HydroDyn['B1Roll']            = False     # (rad); Rotation of the 1st WAMIT body about the global x-axis at the 1st WAMIT body's reference point; 
HydroDyn['B1Pitch']           = False     # (rad); Rotation of the 1st WAMIT body about the global y-axis at the 1st WAMIT body's reference point; 
HydroDyn['B1Yaw']             = False     # (rad); Rotation of the 1st WAMIT body about the global z-axis at the 1st WAMIT body's reference point; 
HydroDyn['B1TVxi']            = False     # (m/s); Translational velocity of the 1st WAMIT body along the global x-axis; 
HydroDyn['B1TVyi']            = False     # (m/s); Translational velocity of the 1st WAMIT body along the global y-axis; 
HydroDyn['B1TVzi']            = False     # (m/s); Translational velocity of the 1st WAMIT body along the global z-axis; 
HydroDyn['B1RVxi']            = False     # (rad/s); Rotational velocity of the 1st WAMIT body about the global x-axis at the 1st WAMIT body's reference point; 
HydroDyn['B1RVyi']            = False     # (rad/s); Rotational velocity of the 1st WAMIT body about the global y-axis at the 1st WAMIT body's reference point; 
HydroDyn['B1RVzi']            = False     # (rad/s); Rotational velocity of the 1st WAMIT body about the global z-axis at the 1st WAMIT body's reference point; 
HydroDyn['B1TAxi']            = False     # (m/s^2); Translational acceleration of the 1st WAMIT body along the global x-axis; 
HydroDyn['B1TAyi']            = False     # (m/s^2); Translational acceleration of the 1st WAMIT body along the global y-axis; 
HydroDyn['B1TAzi']            = False     # (m/s^2); Translational acceleration of the 1st WAMIT body along the global z-axis; 
HydroDyn['B1RAxi']            = False     # (rad/s^2); Rotational acceleration of the 1st WAMIT body about the global x-axis at the 1st WAMIT body's reference point; 
HydroDyn['B1RAyi']            = False     # (rad/s^2); Rotational acceleration of the 1st WAMIT body about the global y-axis at the 1st WAMIT body's reference point; 
HydroDyn['B1RAzi']            = False     # (rad/s^2); Rotational acceleration of the 1st WAMIT body about the global z-axis at the 1st WAMIT body's reference point; 
HydroDyn['B2Surge']           = False     # (m); Displacement of the 2nd WAMIT body along the global x-axis; 
HydroDyn['B2Sway']            = False     # (m); Displacement of the 2nd WAMIT body along the global y-axis; 
HydroDyn['B2Heave']           = False     # (m); Displacement of the 2nd WAMIT body along the global z-axis; 
HydroDyn['B2Roll']            = False     # (rad); Rotation of the 2nd WAMIT body about the global x-axis at the 2nd WAMIT body's reference point; 
HydroDyn['B2Pitch']           = False     # (rad); Rotation of the 2nd WAMIT body about the global y-axis at the 2nd WAMIT body's reference point; 
HydroDyn['B2Yaw']             = False     # (rad); Rotation of the 2nd WAMIT body about the global z-axis at the 2nd WAMIT body's reference point; 
HydroDyn['B2TVxi']            = False     # (m/s); Translational velocity of the 2nd WAMIT body along the global x-axis; 
HydroDyn['B2TVyi']            = False     # (m/s); Translational velocity of the 2nd WAMIT body along the global y-axis; 
HydroDyn['B2TVzi']            = False     # (m/s); Translational velocity of the 2nd WAMIT body along the global z-axis; 
HydroDyn['B2RVxi']            = False     # (rad/s); Rotational velocity of the 2nd WAMIT body about the global x-axis at the 2nd WAMIT body's reference point; 
HydroDyn['B2RVyi']            = False     # (rad/s); Rotational velocity of the 2nd WAMIT body about the global y-axis at the 2nd WAMIT body's reference point; 
HydroDyn['B2RVzi']            = False     # (rad/s); Rotational velocity of the 2nd WAMIT body about the global z-axis at the 2nd WAMIT body's reference point; 
HydroDyn['B2TAxi']            = False     # (m/s^2); Translational acceleration of the 2nd WAMIT body along the global x-axis; 
HydroDyn['B2TAyi']            = False     # (m/s^2); Translational acceleration of the 2nd WAMIT body along the global y-axis; 
HydroDyn['B2TAzi']            = False     # (m/s^2); Translational acceleration of the 2nd WAMIT body along the global z-axis; 
HydroDyn['B2RAxi']            = False     # (rad/s^2); Rotational acceleration of the 2nd WAMIT body about the global x-axis at the 2nd WAMIT body's reference point; 
HydroDyn['B2RAyi']            = False     # (rad/s^2); Rotational acceleration of the 2nd WAMIT body about the global y-axis at the 2nd WAMIT body's reference point; 
HydroDyn['B2RAzi']            = False     # (rad/s^2); Rotational acceleration of the 2nd WAMIT body about the global z-axis at the 2nd WAMIT body's reference point; 
HydroDyn['B3Surge']           = False     # (m); Displacement of the 3rd WAMIT body along the global x-axis; 
HydroDyn['B3Sway']            = False     # (m); Displacement of the 3rd WAMIT body along the global y-axis; 
HydroDyn['B3Heave']           = False     # (m); Displacement of the 3rd WAMIT body along the global z-axis; 
HydroDyn['B3Roll']            = False     # (rad); Rotation of the 3rd WAMIT body about the global x-axis at the 3rd WAMIT body's reference point; 
HydroDyn['B3Pitch']           = False     # (rad); Rotation of the 3rd WAMIT body about the global y-axis at the 3rd WAMIT body's reference point; 
HydroDyn['B3Yaw']             = False     # (rad); Rotation of the 3rd WAMIT body about the global z-axis at the 3rd WAMIT body's reference point; 
HydroDyn['B3TVxi']            = False     # (m/s); Translational velocity of the 3rd WAMIT body along the global x-axis; 
HydroDyn['B3TVyi']            = False     # (m/s); Translational velocity of the 3rd WAMIT body along the global y-axis; 
HydroDyn['B3TVzi']            = False     # (m/s); Translational velocity of the 3rd WAMIT body along the global z-axis; 
HydroDyn['B3RVxi']            = False     # (rad/s); Rotational velocity of the 3rd WAMIT body about the global x-axis at the 3rd WAMIT body's reference point; 
HydroDyn['B3RVyi']            = False     # (rad/s); Rotational velocity of the 3rd WAMIT body about the global y-axis at the 3rd WAMIT body's reference point; 
HydroDyn['B3RVzi']            = False     # (rad/s); Rotational velocity of the 3rd WAMIT body about the global z-axis at the 3rd WAMIT body's reference point; 
HydroDyn['B3TAxi']            = False     # (m/s^2); Translational acceleration of the 3rd WAMIT body along the global x-axis; 
HydroDyn['B3TAyi']            = False     # (m/s^2); Translational acceleration of the 3rd WAMIT body along the global y-axis; 
HydroDyn['B3TAzi']            = False     # (m/s^2); Translational acceleration of the 3rd WAMIT body along the global z-axis; 
HydroDyn['B3RAxi']            = False     # (rad/s^2); Rotational acceleration of the 3rd WAMIT body about the global x-axis at the 3rd WAMIT body's reference point; 
HydroDyn['B3RAyi']            = False     # (rad/s^2); Rotational acceleration of the 3rd WAMIT body about the global y-axis at the 3rd WAMIT body's reference point; 
HydroDyn['B3RAzi']            = False     # (rad/s^2); Rotational acceleration of the 3rd WAMIT body about the global z-axis at the 3rd WAMIT body's reference point; 
HydroDyn['B4Surge']           = False     # (m); Displacement of the 4th WAMIT body along the global x-axis; 
HydroDyn['B4Sway']            = False     # (m); Displacement of the 4th WAMIT body along the global y-axis; 
HydroDyn['B4Heave']           = False     # (m); Displacement of the 4th WAMIT body along the global z-axis; 
HydroDyn['B4Roll']            = False     # (rad); Rotation of the 4th WAMIT body about the global x-axis at the 4th WAMIT body's reference point; 
HydroDyn['B4Pitch']           = False     # (rad); Rotation of the 4th WAMIT body about the global y-axis at the 4th WAMIT body's reference point; 
HydroDyn['B4Yaw']             = False     # (rad); Rotation of the 4th WAMIT body about the global z-axis at the 4th WAMIT body's reference point; 
HydroDyn['B4TVxi']            = False     # (m/s); Translational velocity of the 4th WAMIT body along the global x-axis; 
HydroDyn['B4TVyi']            = False     # (m/s); Translational velocity of the 4th WAMIT body along the global y-axis; 
HydroDyn['B4TVzi']            = False     # (m/s); Translational velocity of the 4th WAMIT body along the global z-axis; 
HydroDyn['B4RVxi']            = False     # (rad/s); Rotational velocity of the 4th WAMIT body about the global x-axis at the 4th WAMIT body's reference point; 
HydroDyn['B4RVyi']            = False     # (rad/s); Rotational velocity of the 4th WAMIT body about the global y-axis at the 4th WAMIT body's reference point; 
HydroDyn['B4RVzi']            = False     # (rad/s); Rotational velocity of the 4th WAMIT body about the global z-axis at the 4th WAMIT body's reference point; 
HydroDyn['B4TAxi']            = False     # (m/s^2); Translational acceleration of the 4th WAMIT body along the global x-axis; 
HydroDyn['B4TAyi']            = False     # (m/s^2); Translational acceleration of the 4th WAMIT body along the global y-axis; 
HydroDyn['B4TAzi']            = False     # (m/s^2); Translational acceleration of the 4th WAMIT body along the global z-axis; 
HydroDyn['B4RAxi']            = False     # (rad/s^2); Rotational acceleration of the 4th WAMIT body about the global x-axis at the 4th WAMIT body's reference point; 
HydroDyn['B4RAyi']            = False     # (rad/s^2); Rotational acceleration of the 4th WAMIT body about the global y-axis at the 4th WAMIT body's reference point; 
HydroDyn['B4RAzi']            = False     # (rad/s^2); Rotational acceleration of the 4th WAMIT body about the global z-axis at the 4th WAMIT body's reference point; 
HydroDyn['B5Surge']           = False     # (m); Displacement of the 5th WAMIT body along the global x-axis; 
HydroDyn['B5Sway']            = False     # (m); Displacement of the 5th WAMIT body along the global y-axis; 
HydroDyn['B5Heave']           = False     # (m); Displacement of the 5th WAMIT body along the global z-axis; 
HydroDyn['B5Roll']            = False     # (rad); Rotation of the 5th WAMIT body about the global x-axis at the 5th WAMIT body's reference point; 
HydroDyn['B5Pitch']           = False     # (rad); Rotation of the 5th WAMIT body about the global y-axis at the 5th WAMIT body's reference point; 
HydroDyn['B5Yaw']             = False     # (rad); Rotation of the 5th WAMIT body about the global z-axis at the 5th WAMIT body's reference point; 
HydroDyn['B5TVxi']            = False     # (m/s); Translational velocity of the 5th WAMIT body along the global x-axis; 
HydroDyn['B5TVyi']            = False     # (m/s); Translational velocity of the 5th WAMIT body along the global y-axis; 
HydroDyn['B5TVzi']            = False     # (m/s); Translational velocity of the 5th WAMIT body along the global z-axis; 
HydroDyn['B5RVxi']            = False     # (rad/s); Rotational velocity of the 5th WAMIT body about the global x-axis at the 5th WAMIT body's reference point; 
HydroDyn['B5RVyi']            = False     # (rad/s); Rotational velocity of the 5th WAMIT body about the global y-axis at the 5th WAMIT body's reference point; 
HydroDyn['B5RVzi']            = False     # (rad/s); Rotational velocity of the 5th WAMIT body about the global z-axis at the 5th WAMIT body's reference point; 
HydroDyn['B5TAxi']            = False     # (m/s^2); Translational acceleration of the 5th WAMIT body along the global x-axis; 
HydroDyn['B5TAyi']            = False     # (m/s^2); Translational acceleration of the 5th WAMIT body along the global y-axis; 
HydroDyn['B5TAzi']            = False     # (m/s^2); Translational acceleration of the 5th WAMIT body along the global z-axis; 
HydroDyn['B5RAxi']            = False     # (rad/s^2); Rotational acceleration of the 5th WAMIT body about the global x-axis at the 5th WAMIT body's reference point; 
HydroDyn['B5RAyi']            = False     # (rad/s^2); Rotational acceleration of the 5th WAMIT body about the global y-axis at the 5th WAMIT body's reference point; 
HydroDyn['B5RAzi']            = False     # (rad/s^2); Rotational acceleration of the 5th WAMIT body about the global z-axis at the 5th WAMIT body's reference point; 
HydroDyn['B6Surge']           = False     # (m); Displacement of the 6th WAMIT body along the global x-axis; 
HydroDyn['B6Sway']            = False     # (m); Displacement of the 6th WAMIT body along the global y-axis; 
HydroDyn['B6Heave']           = False     # (m); Displacement of the 6th WAMIT body along the global z-axis; 
HydroDyn['B6Roll']            = False     # (rad); Rotation of the 6th WAMIT body about the global x-axis at the 6th WAMIT body's reference point; 
HydroDyn['B6Pitch']           = False     # (rad); Rotation of the 6th WAMIT body about the global y-axis at the 6th WAMIT body's reference point; 
HydroDyn['B6Yaw']             = False     # (rad); Rotation of the 6th WAMIT body about the global z-axis at the 6th WAMIT body's reference point; 
HydroDyn['B6TVxi']            = False     # (m/s); Translational velocity of the 6th WAMIT body along the global x-axis; 
HydroDyn['B6TVyi']            = False     # (m/s); Translational velocity of the 6th WAMIT body along the global y-axis; 
HydroDyn['B6TVzi']            = False     # (m/s); Translational velocity of the 6th WAMIT body along the global z-axis; 
HydroDyn['B6RVxi']            = False     # (rad/s); Rotational velocity of the 6th WAMIT body about the global x-axis at the 6th WAMIT body's reference point; 
HydroDyn['B6RVyi']            = False     # (rad/s); Rotational velocity of the 6th WAMIT body about the global y-axis at the 6th WAMIT body's reference point; 
HydroDyn['B6RVzi']            = False     # (rad/s); Rotational velocity of the 6th WAMIT body about the global z-axis at the 6th WAMIT body's reference point; 
HydroDyn['B6TAxi']            = False     # (m/s^2); Translational acceleration of the 6th WAMIT body along the global x-axis; 
HydroDyn['B6TAyi']            = False     # (m/s^2); Translational acceleration of the 6th WAMIT body along the global y-axis; 
HydroDyn['B6TAzi']            = False     # (m/s^2); Translational acceleration of the 6th WAMIT body along the global z-axis; 
HydroDyn['B6RAxi']            = False     # (rad/s^2); Rotational acceleration of the 6th WAMIT body about the global x-axis at the 6th WAMIT body's reference point; 
HydroDyn['B6RAyi']            = False     # (rad/s^2); Rotational acceleration of the 6th WAMIT body about the global y-axis at the 6th WAMIT body's reference point; 
HydroDyn['B6RAzi']            = False     # (rad/s^2); Rotational acceleration of the 6th WAMIT body about the global z-axis at the 6th WAMIT body's reference point; 
HydroDyn['B7Surge']           = False     # (m); Displacement of the 7th WAMIT body along the global x-axis; 
HydroDyn['B7Sway']            = False     # (m); Displacement of the 7th WAMIT body along the global y-axis; 
HydroDyn['B7Heave']           = False     # (m); Displacement of the 7th WAMIT body along the global z-axis; 
HydroDyn['B7Roll']            = False     # (rad); Rotation of the 7th WAMIT body about the global x-axis at the 7th WAMIT body's reference point; 
HydroDyn['B7Pitch']           = False     # (rad); Rotation of the 7th WAMIT body about the global y-axis at the 7th WAMIT body's reference point; 
HydroDyn['B7Yaw']             = False     # (rad); Rotation of the 7th WAMIT body about the global z-axis at the 7th WAMIT body's reference point; 
HydroDyn['B7TVxi']            = False     # (m/s); Translational velocity of the 7th WAMIT body along the global x-axis; 
HydroDyn['B7TVyi']            = False     # (m/s); Translational velocity of the 7th WAMIT body along the global y-axis; 
HydroDyn['B7TVzi']            = False     # (m/s); Translational velocity of the 7th WAMIT body along the global z-axis; 
HydroDyn['B7RVxi']            = False     # (rad/s); Rotational velocity of the 7th WAMIT body about the global x-axis at the 7th WAMIT body's reference point; 
HydroDyn['B7RVyi']            = False     # (rad/s); Rotational velocity of the 7th WAMIT body about the global y-axis at the 7th WAMIT body's reference point; 
HydroDyn['B7RVzi']            = False     # (rad/s); Rotational velocity of the 7th WAMIT body about the global z-axis at the 7th WAMIT body's reference point; 
HydroDyn['B7TAxi']            = False     # (m/s^2); Translational acceleration of the 7th WAMIT body along the global x-axis; 
HydroDyn['B7TAyi']            = False     # (m/s^2); Translational acceleration of the 7th WAMIT body along the global y-axis; 
HydroDyn['B7TAzi']            = False     # (m/s^2); Translational acceleration of the 7th WAMIT body along the global z-axis; 
HydroDyn['B7RAxi']            = False     # (rad/s^2); Rotational acceleration of the 7th WAMIT body about the global x-axis at the 7th WAMIT body's reference point; 
HydroDyn['B7RAyi']            = False     # (rad/s^2); Rotational acceleration of the 7th WAMIT body about the global y-axis at the 7th WAMIT body's reference point; 
HydroDyn['B7RAzi']            = False     # (rad/s^2); Rotational acceleration of the 7th WAMIT body about the global z-axis at the 7th WAMIT body's reference point; 
HydroDyn['B8Surge']           = False     # (m); Displacement of the 8th WAMIT body along the global x-axis; 
HydroDyn['B8Sway']            = False     # (m); Displacement of the 8th WAMIT body along the global y-axis; 
HydroDyn['B8Heave']           = False     # (m); Displacement of the 8th WAMIT body along the global z-axis; 
HydroDyn['B8Roll']            = False     # (rad); Rotation of the 8th WAMIT body about the global x-axis at the 8th WAMIT body's reference point; 
HydroDyn['B8Pitch']           = False     # (rad); Rotation of the 8th WAMIT body about the global y-axis at the 8th WAMIT body's reference point; 
HydroDyn['B8Yaw']             = False     # (rad); Rotation of the 8th WAMIT body about the global z-axis at the 8th WAMIT body's reference point; 
HydroDyn['B8TVxi']            = False     # (m/s); Translational velocity of the 8th WAMIT body along the global x-axis; 
HydroDyn['B8TVyi']            = False     # (m/s); Translational velocity of the 8th WAMIT body along the global y-axis; 
HydroDyn['B8TVzi']            = False     # (m/s); Translational velocity of the 8th WAMIT body along the global z-axis; 
HydroDyn['B8RVxi']            = False     # (rad/s); Rotational velocity of the 8th WAMIT body about the global x-axis at the 8th WAMIT body's reference point; 
HydroDyn['B8RVyi']            = False     # (rad/s); Rotational velocity of the 8th WAMIT body about the global y-axis at the 8th WAMIT body's reference point; 
HydroDyn['B8RVzi']            = False     # (rad/s); Rotational velocity of the 8th WAMIT body about the global z-axis at the 8th WAMIT body's reference point; 
HydroDyn['B8TAxi']            = False     # (m/s^2); Translational acceleration of the 8th WAMIT body along the global x-axis; 
HydroDyn['B8TAyi']            = False     # (m/s^2); Translational acceleration of the 8th WAMIT body along the global y-axis; 
HydroDyn['B8TAzi']            = False     # (m/s^2); Translational acceleration of the 8th WAMIT body along the global z-axis; 
HydroDyn['B8RAxi']            = False     # (rad/s^2); Rotational acceleration of the 8th WAMIT body about the global x-axis at the 8th WAMIT body's reference point; 
HydroDyn['B8RAyi']            = False     # (rad/s^2); Rotational acceleration of the 8th WAMIT body about the global y-axis at the 8th WAMIT body's reference point; 
HydroDyn['B8RAzi']            = False     # (rad/s^2); Rotational acceleration of the 8th WAMIT body about the global z-axis at the 8th WAMIT body's reference point; 
HydroDyn['B9Surge']           = False     # (m); Displacement of the 9th WAMIT body along the global x-axis; 
HydroDyn['B9Sway']            = False     # (m); Displacement of the 9th WAMIT body along the global y-axis; 
HydroDyn['B9Heave']           = False     # (m); Displacement of the 9th WAMIT body along the global z-axis; 
HydroDyn['B9Roll']            = False     # (rad); Rotation of the 9th WAMIT body about the global x-axis at the 9th WAMIT body's reference point; 
HydroDyn['B9Pitch']           = False     # (rad); Rotation of the 9th WAMIT body about the global y-axis at the 9th WAMIT body's reference point; 
HydroDyn['B9Yaw']             = False     # (rad); Rotation of the 9th WAMIT body about the global z-axis at the 9th WAMIT body's reference point; 
HydroDyn['B9TVxi']            = False     # (m/s); Translational velocity of the 9th WAMIT body along the global x-axis; 
HydroDyn['B9TVyi']            = False     # (m/s); Translational velocity of the 9th WAMIT body along the global y-axis; 
HydroDyn['B9TVzi']            = False     # (m/s); Translational velocity of the 9th WAMIT body along the global z-axis; 
HydroDyn['B9RVxi']            = False     # (rad/s); Rotational velocity of the 9th WAMIT body about the global x-axis at the 9th WAMIT body's reference point; 
HydroDyn['B9RVyi']            = False     # (rad/s); Rotational velocity of the 9th WAMIT body about the global y-axis at the 9th WAMIT body's reference point; 
HydroDyn['B9RVzi']            = False     # (rad/s); Rotational velocity of the 9th WAMIT body about the global z-axis at the 9th WAMIT body's reference point; 
HydroDyn['B9TAxi']            = False     # (m/s^2); Translational acceleration of the 9th WAMIT body along the global x-axis; 
HydroDyn['B9TAyi']            = False     # (m/s^2); Translational acceleration of the 9th WAMIT body along the global y-axis; 
HydroDyn['B9TAzi']            = False     # (m/s^2); Translational acceleration of the 9th WAMIT body along the global z-axis; 
HydroDyn['B9RAxi']            = False     # (rad/s^2); Rotational acceleration of the 9th WAMIT body about the global x-axis at the 9th WAMIT body's reference point; 
HydroDyn['B9RAyi']            = False     # (rad/s^2); Rotational acceleration of the 9th WAMIT body about the global y-axis at the 9th WAMIT body's reference point; 
HydroDyn['B9RAzi']            = False     # (rad/s^2); Rotational acceleration of the 9th WAMIT body about the global z-axis at the 9th WAMIT body's reference point; 

# WAMIT Body Forces
HydroDyn['B1AddFxi']          = False     # (N); Force along the global x-axis due to additional preload, stiffness, and damping of the 1st WAMIT body ; 
HydroDyn['B1AddFyi']          = False     # (N); Force along the global y-axis due to additional preload, stiffness, and damping of the 1st WAMIT body ; 
HydroDyn['B1AddFzi']          = False     # (N); Force along the global z-axis due to additional preload, stiffness, and damping of the 1st WAMIT body ; 
HydroDyn['B1AddMxi']          = False     # (N-m); Moment about the global x-axis at of the 1st WAMIT body's reference point due to additional preload, stiffness, and damping ; 
HydroDyn['B1AddMyi']          = False     # (N-m); Moment about the global y-axis at of the 1st WAMIT body's reference point due to additional preload, stiffness, and damping ; 
HydroDyn['B1AddMzi']          = False     # (N-m); Moment about the global z-axis at of the 1st WAMIT body's reference point due to additional preload, stiffness, and damping ; 
HydroDyn['B1WvsF1xi']         = False     # (N); First-order wave-excitation force at the 1st WAMIT body  from diffraction  along the global x-axis; 
HydroDyn['B1WvsF1yi']         = False     # (N); First-order wave-excitation force at the 1st WAMIT body  from diffraction  along the global y-axis; 
HydroDyn['B1WvsF1zi']         = False     # (N); First-order wave-excitation force at the 1st WAMIT body  from diffraction  along the global z-axis; 
HydroDyn['B1WvsM1xi']         = False     # (N-m); First-order wave-excitation moment at the 1st WAMIT body reference point  from diffraction  about the global x-axis; 
HydroDyn['B1WvsM1yi']         = False     # (N-m); First-order wave-excitation moment at the 1st WAMIT body reference point  from diffraction  about the global y-axis; 
HydroDyn['B1WvsM1zi']         = False     # (N-m); First-order wave-excitation moment at the 1st WAMIT body reference point  from diffraction  about the global z-axis; 
HydroDyn['B1WvsFxi']          = False     # (N); Total (first-order plus second-order) wave-excitation force at the 1st WAMIT body  from diffraction  along the global x-axis; 
HydroDyn['B1WvsFyi']          = False     # (N); Total (first-order plus second-order) wave-excitation force at the 1st WAMIT body  from diffraction  along the global y-axis; 
HydroDyn['B1WvsFzi']          = False     # (N); Total (first-order plus second-order) wave-excitation force at the 1st WAMIT body  from diffraction  along the global z-axis; 
HydroDyn['B1WvsMxi']          = False     # (N-m); Total (first-order plus second-order) wave-excitation moment at the 1st WAMIT body reference point  from diffraction  about the global x-axis; 
HydroDyn['B1WvsMyi']          = False     # (N-m); Total (first-order plus second-order) wave-excitation moment at the 1st WAMIT body reference point  from diffraction  about the global y-axis; 
HydroDyn['B1WvsMzi']          = False     # (N-m); Total (first-order plus second-order) wave-excitation moment at the 1st WAMIT body reference point  from diffraction  about the global z-axis; 
HydroDyn['B1HdSFxi']          = False     # (N); Hydrostatic force from the 1st WAMIT body along the global x-axis; 
HydroDyn['B1HdSFyi']          = False     # (N); Hydrostatic force from the 1st WAMIT body along the global y-axis; 
HydroDyn['B1HdSFzi']          = False     # (N); Hydrostatic force from the 1st WAMIT body along the global z-axis; 
HydroDyn['B1HdSMxi']          = False     # (N-m); Hydrostatic moment from the 1st WAMIT body about the global x-axis at the 1st WAMT body reference point; 
HydroDyn['B1HdSMyi']          = False     # (N-m); Hydrostatic moment from the 1st WAMIT body about the global y-axis at the 1st WAMT body reference point; 
HydroDyn['B1HdSMzi']          = False     # (N-m); Hydrostatic moment from the 1st WAMIT body about the global z-axis at the 1st WAMT body reference point; 
HydroDyn['B1RdtFxi']          = False     # (N); Wave-radiation force at the 1st WAMIT body along the global x-axis; 
HydroDyn['B1RdtFyi']          = False     # (N); Wave-radiation force at the 1st WAMIT body along the global y-axis; 
HydroDyn['B1RdtFzi']          = False     # (N); Wave-radiation force at the 1st WAMIT body along the global z-axis; 
HydroDyn['B1RdtMxi']          = False     # (N-m); Wave-radiation moment at the 1st WAMIT body about the global x-axis at the 1st WAMIT body's reference point; 
HydroDyn['B1RdtMyi']          = False     # (N-m); Wave-radiation moment at the 1st WAMIT body about the global y-axis at the 1st WAMIT body's reference point; 
HydroDyn['B1RdtMzi']          = False     # (N-m); Wave-radiation moment at the 1st WAMIT body about the global z-axis at the 1st WAMIT body's reference point; 
HydroDyn['B2AddFxi']          = False     # (N); Force along the global x-axis due to additional preload, stiffness, and damping of the 2nd WAMIT body ; 
HydroDyn['B2AddFyi']          = False     # (N); Force along the global y-axis due to additional preload, stiffness, and damping of the 2nd WAMIT body ; 
HydroDyn['B2AddFzi']          = False     # (N); Force along the global z-axis due to additional preload, stiffness, and damping of the 2nd WAMIT body ; 
HydroDyn['B2AddMxi']          = False     # (N-m); Moment about the global x-axis at of the 2nd WAMIT body's reference point due to additional preload, stiffness, and damping ; 
HydroDyn['B2AddMyi']          = False     # (N-m); Moment about the global y-axis at of the 2nd WAMIT body's reference point due to additional preload, stiffness, and damping ; 
HydroDyn['B2AddMzi']          = False     # (N-m); Moment about the global z-axis at of the 2nd WAMIT body's reference point due to additional preload, stiffness, and damping ; 
HydroDyn['B2WvsF1xi']         = False     # (N); First-order wave-excitation force at the 2nd WAMIT body  from diffraction  along the global x-axis; 
HydroDyn['B2WvsF1yi']         = False     # (N); First-order wave-excitation force at the 2nd WAMIT body  from diffraction  along the global y-axis; 
HydroDyn['B2WvsF1zi']         = False     # (N); First-order wave-excitation force at the 2nd WAMIT body  from diffraction  along the global z-axis; 
HydroDyn['B2WvsM1xi']         = False     # (N-m); First-order wave-excitation moment at the 2nd WAMIT body reference point  from diffraction  about the global x-axis; 
HydroDyn['B2WvsM1yi']         = False     # (N-m); First-order wave-excitation moment at the 2nd WAMIT body reference point  from diffraction  about the global y-axis; 
HydroDyn['B2WvsM1zi']         = False     # (N-m); First-order wave-excitation moment at the 2nd WAMIT body reference point  from diffraction  about the global z-axis; 
HydroDyn['B2WvsFxi']          = False     # (N); Total (first-order plus second-order) wave-excitation force at the 2nd WAMIT body  from diffraction  along the global x-axis; 
HydroDyn['B2WvsFyi']          = False     # (N); Total (first-order plus second-order) wave-excitation force at the 2nd WAMIT body  from diffraction  along the global y-axis; 
HydroDyn['B2WvsFzi']          = False     # (N); Total (first-order plus second-order) wave-excitation force at the 2nd WAMIT body  from diffraction  along the global z-axis; 
HydroDyn['B2WvsMxi']          = False     # (N-m); Total (first-order plus second-order) wave-excitation moment at the 2nd WAMIT body reference point  from diffraction  about the global x-axis; 
HydroDyn['B2WvsMyi']          = False     # (N-m); Total (first-order plus second-order) wave-excitation moment at the 2nd WAMIT body reference point  from diffraction  about the global y-axis; 
HydroDyn['B2WvsMzi']          = False     # (N-m); Total (first-order plus second-order) wave-excitation moment at the 2nd WAMIT body reference point  from diffraction  about the global z-axis; 
HydroDyn['B2HdSFxi']          = False     # (N); Hydrostatic force from the 2nd WAMIT body along the global x-axis; 
HydroDyn['B2HdSFyi']          = False     # (N); Hydrostatic force from the 2nd WAMIT body along the global y-axis; 
HydroDyn['B2HdSFzi']          = False     # (N); Hydrostatic force from the 2nd WAMIT body along the global z-axis; 
HydroDyn['B2HdSMxi']          = False     # (N-m); Hydrostatic moment from the 2nd WAMIT body about the global x-axis at the 2nd WAMT body reference point; 
HydroDyn['B2HdSMyi']          = False     # (N-m); Hydrostatic moment from the 2nd WAMIT body about the global y-axis at the 2nd WAMT body reference point; 
HydroDyn['B2HdSMzi']          = False     # (N-m); Hydrostatic moment from the 2nd WAMIT body about the global z-axis at the 2nd WAMT body reference point; 
HydroDyn['B2RdtFxi']          = False     # (N); Wave-radiation force at the 2nd WAMIT body along the global x-axis; 
HydroDyn['B2RdtFyi']          = False     # (N); Wave-radiation force at the 2nd WAMIT body along the global y-axis; 
HydroDyn['B2RdtFzi']          = False     # (N); Wave-radiation force at the 2nd WAMIT body along the global z-axis; 
HydroDyn['B2RdtMxi']          = False     # (N-m); Wave-radiation moment at the 2nd WAMIT body about the global x-axis at the 2nd WAMIT body's reference point; 
HydroDyn['B2RdtMyi']          = False     # (N-m); Wave-radiation moment at the 2nd WAMIT body about the global y-axis at the 2nd WAMIT body's reference point; 
HydroDyn['B2RdtMzi']          = False     # (N-m); Wave-radiation moment at the 2nd WAMIT body about the global z-axis at the 2nd WAMIT body's reference point; 
HydroDyn['B3AddFxi']          = False     # (N); Force along the global x-axis due to additional preload, stiffness, and damping of the 3rd WAMIT body ; 
HydroDyn['B3AddFyi']          = False     # (N); Force along the global y-axis due to additional preload, stiffness, and damping of the 3rd WAMIT body ; 
HydroDyn['B3AddFzi']          = False     # (N); Force along the global z-axis due to additional preload, stiffness, and damping of the 3rd WAMIT body ; 
HydroDyn['B3AddMxi']          = False     # (N-m); Moment about the global x-axis at of the 3rd WAMIT body's reference point due to additional preload, stiffness, and damping ; 
HydroDyn['B3AddMyi']          = False     # (N-m); Moment about the global y-axis at of the 3rd WAMIT body's reference point due to additional preload, stiffness, and damping ; 
HydroDyn['B3AddMzi']          = False     # (N-m); Moment about the global z-axis at of the 3rd WAMIT body's reference point due to additional preload, stiffness, and damping ; 
HydroDyn['B3WvsF1xi']         = False     # (N); First-order wave-excitation force at the 3rd WAMIT body  from diffraction  along the global x-axis; 
HydroDyn['B3WvsF1yi']         = False     # (N); First-order wave-excitation force at the 3rd WAMIT body  from diffraction  along the global y-axis; 
HydroDyn['B3WvsF1zi']         = False     # (N); First-order wave-excitation force at the 3rd WAMIT body  from diffraction  along the global z-axis; 
HydroDyn['B3WvsM1xi']         = False     # (N-m); First-order wave-excitation moment at the 3rd WAMIT body reference point  from diffraction  about the global x-axis; 
HydroDyn['B3WvsM1yi']         = False     # (N-m); First-order wave-excitation moment at the 3rd WAMIT body reference point  from diffraction  about the global y-axis; 
HydroDyn['B3WvsM1zi']         = False     # (N-m); First-order wave-excitation moment at the 3rd WAMIT body reference point  from diffraction  about the global z-axis; 
HydroDyn['B3WvsFxi']          = False     # (N); Total (first-order plus second-order) wave-excitation force at the 3rd WAMIT body  from diffraction  along the global x-axis; 
HydroDyn['B3WvsFyi']          = False     # (N); Total (first-order plus second-order) wave-excitation force at the 3rd WAMIT body  from diffraction  along the global y-axis; 
HydroDyn['B3WvsFzi']          = False     # (N); Total (first-order plus second-order) wave-excitation force at the 3rd WAMIT body  from diffraction  along the global z-axis; 
HydroDyn['B3WvsMxi']          = False     # (N-m); Total (first-order plus second-order) wave-excitation moment at the 3rd WAMIT body reference point  from diffraction  about the global x-axis; 
HydroDyn['B3WvsMyi']          = False     # (N-m); Total (first-order plus second-order) wave-excitation moment at the 3rd WAMIT body reference point  from diffraction  about the global y-axis; 
HydroDyn['B3WvsMzi']          = False     # (N-m); Total (first-order plus second-order) wave-excitation moment at the 3rd WAMIT body reference point  from diffraction  about the global z-axis; 
HydroDyn['B3HdSFxi']          = False     # (N); Hydrostatic force from the 3rd WAMIT body along the global x-axis; 
HydroDyn['B3HdSFyi']          = False     # (N); Hydrostatic force from the 3rd WAMIT body along the global y-axis; 
HydroDyn['B3HdSFzi']          = False     # (N); Hydrostatic force from the 3rd WAMIT body along the global z-axis; 
HydroDyn['B3HdSMxi']          = False     # (N-m); Hydrostatic moment from the 3rd WAMIT body about the global x-axis at the 3rd WAMT body reference point; 
HydroDyn['B3HdSMyi']          = False     # (N-m); Hydrostatic moment from the 3rd WAMIT body about the global y-axis at the 3rd WAMT body reference point; 
HydroDyn['B3HdSMzi']          = False     # (N-m); Hydrostatic moment from the 3rd WAMIT body about the global z-axis at the 3rd WAMT body reference point; 
HydroDyn['B3RdtFxi']          = False     # (N); Wave-radiation force at the 3rd WAMIT body along the global x-axis; 
HydroDyn['B3RdtFyi']          = False     # (N); Wave-radiation force at the 3rd WAMIT body along the global y-axis; 
HydroDyn['B3RdtFzi']          = False     # (N); Wave-radiation force at the 3rd WAMIT body along the global z-axis; 
HydroDyn['B3RdtMxi']          = False     # (N-m); Wave-radiation moment at the 3rd WAMIT body about the global x-axis at the 3rd WAMIT body's reference point; 
HydroDyn['B3RdtMyi']          = False     # (N-m); Wave-radiation moment at the 3rd WAMIT body about the global y-axis at the 3rd WAMIT body's reference point; 
HydroDyn['B3RdtMzi']          = False     # (N-m); Wave-radiation moment at the 3rd WAMIT body about the global z-axis at the 3rd WAMIT body's reference point; 
HydroDyn['B4AddFxi']          = False     # (N); Force along the global x-axis due to additional preload, stiffness, and damping of the 4th WAMIT body ; 
HydroDyn['B4AddFyi']          = False     # (N); Force along the global y-axis due to additional preload, stiffness, and damping of the 4th WAMIT body ; 
HydroDyn['B4AddFzi']          = False     # (N); Force along the global z-axis due to additional preload, stiffness, and damping of the 4th WAMIT body ; 
HydroDyn['B4AddMxi']          = False     # (N-m); Moment about the global x-axis at of the 4th WAMIT body's reference point due to additional preload, stiffness, and damping ; 
HydroDyn['B4AddMyi']          = False     # (N-m); Moment about the global y-axis at of the 4th WAMIT body's reference point due to additional preload, stiffness, and damping ; 
HydroDyn['B4AddMzi']          = False     # (N-m); Moment about the global z-axis at of the 4th WAMIT body's reference point due to additional preload, stiffness, and damping ; 
HydroDyn['B4WvsF1xi']         = False     # (N); First-order wave-excitation force at the 4th WAMIT body  from diffraction  along the global x-axis; 
HydroDyn['B4WvsF1yi']         = False     # (N); First-order wave-excitation force at the 4th WAMIT body  from diffraction  along the global y-axis; 
HydroDyn['B4WvsF1zi']         = False     # (N); First-order wave-excitation force at the 4th WAMIT body  from diffraction  along the global z-axis; 
HydroDyn['B4WvsM1xi']         = False     # (N-m); First-order wave-excitation moment at the 4th WAMIT body reference point  from diffraction  about the global x-axis; 
HydroDyn['B4WvsM1yi']         = False     # (N-m); First-order wave-excitation moment at the 4th WAMIT body reference point  from diffraction  about the global y-axis; 
HydroDyn['B4WvsM1zi']         = False     # (N-m); First-order wave-excitation moment at the 4th WAMIT body reference point  from diffraction  about the global z-axis; 
HydroDyn['B4WvsFxi']          = False     # (N); Total (first-order plus second-order) wave-excitation force at the 4th WAMIT body  from diffraction  along the global x-axis; 
HydroDyn['B4WvsFyi']          = False     # (N); Total (first-order plus second-order) wave-excitation force at the 4th WAMIT body  from diffraction  along the global y-axis; 
HydroDyn['B4WvsFzi']          = False     # (N); Total (first-order plus second-order) wave-excitation force at the 4th WAMIT body  from diffraction  along the global z-axis; 
HydroDyn['B4WvsMxi']          = False     # (N-m); Total (first-order plus second-order) wave-excitation moment at the 4th WAMIT body reference point  from diffraction  about the global x-axis; 
HydroDyn['B4WvsMyi']          = False     # (N-m); Total (first-order plus second-order) wave-excitation moment at the 4th WAMIT body reference point  from diffraction  about the global y-axis; 
HydroDyn['B4WvsMzi']          = False     # (N-m); Total (first-order plus second-order) wave-excitation moment at the 4th WAMIT body reference point  from diffraction  about the global z-axis; 
HydroDyn['B4HdSFxi']          = False     # (N); Hydrostatic force from the 4th WAMIT body along the global x-axis; 
HydroDyn['B4HdSFyi']          = False     # (N); Hydrostatic force from the 4th WAMIT body along the global y-axis; 
HydroDyn['B4HdSFzi']          = False     # (N); Hydrostatic force from the 4th WAMIT body along the global z-axis; 
HydroDyn['B4HdSMxi']          = False     # (N-m); Hydrostatic moment from the 4th WAMIT body about the global x-axis at the 4th WAMT body reference point; 
HydroDyn['B4HdSMyi']          = False     # (N-m); Hydrostatic moment from the 4th WAMIT body about the global y-axis at the 4th WAMT body reference point; 
HydroDyn['B4HdSMzi']          = False     # (N-m); Hydrostatic moment from the 4th WAMIT body about the global z-axis at the 4th WAMT body reference point; 
HydroDyn['B4RdtFxi']          = False     # (N); Wave-radiation force at the 4th WAMIT body along the global x-axis; 
HydroDyn['B4RdtFyi']          = False     # (N); Wave-radiation force at the 4th WAMIT body along the global y-axis; 
HydroDyn['B4RdtFzi']          = False     # (N); Wave-radiation force at the 4th WAMIT body along the global z-axis; 
HydroDyn['B4RdtMxi']          = False     # (N-m); Wave-radiation moment at the 4th WAMIT body about the global x-axis at the 4th WAMIT body's reference point; 
HydroDyn['B4RdtMyi']          = False     # (N-m); Wave-radiation moment at the 4th WAMIT body about the global y-axis at the 4th WAMIT body's reference point; 
HydroDyn['B4RdtMzi']          = False     # (N-m); Wave-radiation moment at the 4th WAMIT body about the global z-axis at the 4th WAMIT body's reference point; 
HydroDyn['B5AddFxi']          = False     # (N); Force along the global x-axis due to additional preload, stiffness, and damping of the 5th WAMIT body ; 
HydroDyn['B5AddFyi']          = False     # (N); Force along the global y-axis due to additional preload, stiffness, and damping of the 5th WAMIT body ; 
HydroDyn['B5AddFzi']          = False     # (N); Force along the global z-axis due to additional preload, stiffness, and damping of the 5th WAMIT body ; 
HydroDyn['B5AddMxi']          = False     # (N-m); Moment about the global x-axis at of the 5th WAMIT body's reference point due to additional preload, stiffness, and damping ; 
HydroDyn['B5AddMyi']          = False     # (N-m); Moment about the global y-axis at of the 5th WAMIT body's reference point due to additional preload, stiffness, and damping ; 
HydroDyn['B5AddMzi']          = False     # (N-m); Moment about the global z-axis at of the 5th WAMIT body's reference point due to additional preload, stiffness, and damping ; 
HydroDyn['B5WvsF1xi']         = False     # (N); First-order wave-excitation force at the 5th WAMIT body  from diffraction  along the global x-axis; 
HydroDyn['B5WvsF1yi']         = False     # (N); First-order wave-excitation force at the 5th WAMIT body  from diffraction  along the global y-axis; 
HydroDyn['B5WvsF1zi']         = False     # (N); First-order wave-excitation force at the 5th WAMIT body  from diffraction  along the global z-axis; 
HydroDyn['B5WvsM1xi']         = False     # (N-m); First-order wave-excitation moment at the 5th WAMIT body reference point  from diffraction  about the global x-axis; 
HydroDyn['B5WvsM1yi']         = False     # (N-m); First-order wave-excitation moment at the 5th WAMIT body reference point  from diffraction  about the global y-axis; 
HydroDyn['B5WvsM1zi']         = False     # (N-m); First-order wave-excitation moment at the 5th WAMIT body reference point  from diffraction  about the global z-axis; 
HydroDyn['B5WvsFxi']          = False     # (N); Total (first-order plus second-order) wave-excitation force at the 5th WAMIT body  from diffraction  along the global x-axis; 
HydroDyn['B5WvsFyi']          = False     # (N); Total (first-order plus second-order) wave-excitation force at the 5th WAMIT body  from diffraction  along the global y-axis; 
HydroDyn['B5WvsFzi']          = False     # (N); Total (first-order plus second-order) wave-excitation force at the 5th WAMIT body  from diffraction  along the global z-axis; 
HydroDyn['B5WvsMxi']          = False     # (N-m); Total (first-order plus second-order) wave-excitation moment at the 5th WAMIT body reference point  from diffraction  about the global x-axis; 
HydroDyn['B5WvsMyi']          = False     # (N-m); Total (first-order plus second-order) wave-excitation moment at the 5th WAMIT body reference point  from diffraction  about the global y-axis; 
HydroDyn['B5WvsMzi']          = False     # (N-m); Total (first-order plus second-order) wave-excitation moment at the 5th WAMIT body reference point  from diffraction  about the global z-axis; 
HydroDyn['B5HdSFxi']          = False     # (N); Hydrostatic force from the 5th WAMIT body along the global x-axis; 
HydroDyn['B5HdSFyi']          = False     # (N); Hydrostatic force from the 5th WAMIT body along the global y-axis; 
HydroDyn['B5HdSFzi']          = False     # (N); Hydrostatic force from the 5th WAMIT body along the global z-axis; 
HydroDyn['B5HdSMxi']          = False     # (N-m); Hydrostatic moment from the 5th WAMIT body about the global x-axis at the 5th WAMT body reference point; 
HydroDyn['B5HdSMyi']          = False     # (N-m); Hydrostatic moment from the 5th WAMIT body about the global y-axis at the 5th WAMT body reference point; 
HydroDyn['B5HdSMzi']          = False     # (N-m); Hydrostatic moment from the 5th WAMIT body about the global z-axis at the 5th WAMT body reference point; 
HydroDyn['B5RdtFxi']          = False     # (N); Wave-radiation force at the 5th WAMIT body along the global x-axis; 
HydroDyn['B5RdtFyi']          = False     # (N); Wave-radiation force at the 5th WAMIT body along the global y-axis; 
HydroDyn['B5RdtFzi']          = False     # (N); Wave-radiation force at the 5th WAMIT body along the global z-axis; 
HydroDyn['B5RdtMxi']          = False     # (N-m); Wave-radiation moment at the 5th WAMIT body about the global x-axis at the 5th WAMIT body's reference point; 
HydroDyn['B5RdtMyi']          = False     # (N-m); Wave-radiation moment at the 5th WAMIT body about the global y-axis at the 5th WAMIT body's reference point; 
HydroDyn['B5RdtMzi']          = False     # (N-m); Wave-radiation moment at the 5th WAMIT body about the global z-axis at the 5th WAMIT body's reference point; 
HydroDyn['B6AddFxi']          = False     # (N); Force along the global x-axis due to additional preload, stiffness, and damping of the 6th WAMIT body ; 
HydroDyn['B6AddFyi']          = False     # (N); Force along the global y-axis due to additional preload, stiffness, and damping of the 6th WAMIT body ; 
HydroDyn['B6AddFzi']          = False     # (N); Force along the global z-axis due to additional preload, stiffness, and damping of the 6th WAMIT body ; 
HydroDyn['B6AddMxi']          = False     # (N-m); Moment about the global x-axis at of the 6th WAMIT body's reference point due to additional preload, stiffness, and damping ; 
HydroDyn['B6AddMyi']          = False     # (N-m); Moment about the global y-axis at of the 6th WAMIT body's reference point due to additional preload, stiffness, and damping ; 
HydroDyn['B6AddMzi']          = False     # (N-m); Moment about the global z-axis at of the 6th WAMIT body's reference point due to additional preload, stiffness, and damping ; 
HydroDyn['B6WvsF1xi']         = False     # (N); First-order wave-excitation force at the 6th WAMIT body  from diffraction  along the global x-axis; 
HydroDyn['B6WvsF1yi']         = False     # (N); First-order wave-excitation force at the 6th WAMIT body  from diffraction  along the global y-axis; 
HydroDyn['B6WvsF1zi']         = False     # (N); First-order wave-excitation force at the 6th WAMIT body  from diffraction  along the global z-axis; 
HydroDyn['B6WvsM1xi']         = False     # (N-m); First-order wave-excitation moment at the 6th WAMIT body reference point  from diffraction  about the global x-axis; 
HydroDyn['B6WvsM1yi']         = False     # (N-m); First-order wave-excitation moment at the 6th WAMIT body reference point  from diffraction  about the global y-axis; 
HydroDyn['B6WvsM1zi']         = False     # (N-m); First-order wave-excitation moment at the 6th WAMIT body reference point  from diffraction  about the global z-axis; 
HydroDyn['B6WvsFxi']          = False     # (N); Total (first-order plus second-order) wave-excitation force at the 6th WAMIT body  from diffraction  along the global x-axis; 
HydroDyn['B6WvsFyi']          = False     # (N); Total (first-order plus second-order) wave-excitation force at the 6th WAMIT body  from diffraction  along the global y-axis; 
HydroDyn['B6WvsFzi']          = False     # (N); Total (first-order plus second-order) wave-excitation force at the 6th WAMIT body  from diffraction  along the global z-axis; 
HydroDyn['B6WvsMxi']          = False     # (N-m); Total (first-order plus second-order) wave-excitation moment at the 6th WAMIT body reference point  from diffraction  about the global x-axis; 
HydroDyn['B6WvsMyi']          = False     # (N-m); Total (first-order plus second-order) wave-excitation moment at the 6th WAMIT body reference point  from diffraction  about the global y-axis; 
HydroDyn['B6WvsMzi']          = False     # (N-m); Total (first-order plus second-order) wave-excitation moment at the 6th WAMIT body reference point  from diffraction  about the global z-axis; 
HydroDyn['B6HdSFxi']          = False     # (N); Hydrostatic force from the 6th WAMIT body along the global x-axis; 
HydroDyn['B6HdSFyi']          = False     # (N); Hydrostatic force from the 6th WAMIT body along the global y-axis; 
HydroDyn['B6HdSFzi']          = False     # (N); Hydrostatic force from the 6th WAMIT body along the global z-axis; 
HydroDyn['B6HdSMxi']          = False     # (N-m); Hydrostatic moment from the 6th WAMIT body about the global x-axis at the 6th WAMT body reference point; 
HydroDyn['B6HdSMyi']          = False     # (N-m); Hydrostatic moment from the 6th WAMIT body about the global y-axis at the 6th WAMT body reference point; 
HydroDyn['B6HdSMzi']          = False     # (N-m); Hydrostatic moment from the 6th WAMIT body about the global z-axis at the 6th WAMT body reference point; 
HydroDyn['B6RdtFxi']          = False     # (N); Wave-radiation force at the 6th WAMIT body along the global x-axis; 
HydroDyn['B6RdtFyi']          = False     # (N); Wave-radiation force at the 6th WAMIT body along the global y-axis; 
HydroDyn['B6RdtFzi']          = False     # (N); Wave-radiation force at the 6th WAMIT body along the global z-axis; 
HydroDyn['B6RdtMxi']          = False     # (N-m); Wave-radiation moment at the 6th WAMIT body about the global x-axis at the 6th WAMIT body's reference point; 
HydroDyn['B6RdtMyi']          = False     # (N-m); Wave-radiation moment at the 6th WAMIT body about the global y-axis at the 6th WAMIT body's reference point; 
HydroDyn['B6RdtMzi']          = False     # (N-m); Wave-radiation moment at the 6th WAMIT body about the global z-axis at the 6th WAMIT body's reference point; 
HydroDyn['B7AddFxi']          = False     # (N); Force along the global x-axis due to additional preload, stiffness, and damping of the 7th WAMIT body ; 
HydroDyn['B7AddFyi']          = False     # (N); Force along the global y-axis due to additional preload, stiffness, and damping of the 7th WAMIT body ; 
HydroDyn['B7AddFzi']          = False     # (N); Force along the global z-axis due to additional preload, stiffness, and damping of the 7th WAMIT body ; 
HydroDyn['B7AddMxi']          = False     # (N-m); Moment about the global x-axis at of the 7th WAMIT body's reference point due to additional preload, stiffness, and damping ; 
HydroDyn['B7AddMyi']          = False     # (N-m); Moment about the global y-axis at of the 7th WAMIT body's reference point due to additional preload, stiffness, and damping ; 
HydroDyn['B7AddMzi']          = False     # (N-m); Moment about the global z-axis at of the 7th WAMIT body's reference point due to additional preload, stiffness, and damping ; 
HydroDyn['B7WvsF1xi']         = False     # (N); First-order wave-excitation force at the 7th WAMIT body  from diffraction  along the global x-axis; 
HydroDyn['B7WvsF1yi']         = False     # (N); First-order wave-excitation force at the 7th WAMIT body  from diffraction  along the global y-axis; 
HydroDyn['B7WvsF1zi']         = False     # (N); First-order wave-excitation force at the 7th WAMIT body  from diffraction  along the global z-axis; 
HydroDyn['B7WvsM1xi']         = False     # (N-m); First-order wave-excitation moment at the 7th WAMIT body reference point  from diffraction  about the global x-axis; 
HydroDyn['B7WvsM1yi']         = False     # (N-m); First-order wave-excitation moment at the 7th WAMIT body reference point  from diffraction  about the global y-axis; 
HydroDyn['B7WvsM1zi']         = False     # (N-m); First-order wave-excitation moment at the 7th WAMIT body reference point  from diffraction  about the global z-axis; 
HydroDyn['B7WvsFxi']          = False     # (N); Total (first-order plus second-order) wave-excitation force at the 7th WAMIT body  from diffraction  along the global x-axis; 
HydroDyn['B7WvsFyi']          = False     # (N); Total (first-order plus second-order) wave-excitation force at the 7th WAMIT body  from diffraction  along the global y-axis; 
HydroDyn['B7WvsFzi']          = False     # (N); Total (first-order plus second-order) wave-excitation force at the 7th WAMIT body  from diffraction  along the global z-axis; 
HydroDyn['B7WvsMxi']          = False     # (N-m); Total (first-order plus second-order) wave-excitation moment at the 7th WAMIT body reference point  from diffraction  about the global x-axis; 
HydroDyn['B7WvsMyi']          = False     # (N-m); Total (first-order plus second-order) wave-excitation moment at the 7th WAMIT body reference point  from diffraction  about the global y-axis; 
HydroDyn['B7WvsMzi']          = False     # (N-m); Total (first-order plus second-order) wave-excitation moment at the 7th WAMIT body reference point  from diffraction  about the global z-axis; 
HydroDyn['B7HdSFxi']          = False     # (N); Hydrostatic force from the 7th WAMIT body along the global x-axis; 
HydroDyn['B7HdSFyi']          = False     # (N); Hydrostatic force from the 7th WAMIT body along the global y-axis; 
HydroDyn['B7HdSFzi']          = False     # (N); Hydrostatic force from the 7th WAMIT body along the global z-axis; 
HydroDyn['B7HdSMxi']          = False     # (N-m); Hydrostatic moment from the 7th WAMIT body about the global x-axis at the 7th WAMT body reference point; 
HydroDyn['B7HdSMyi']          = False     # (N-m); Hydrostatic moment from the 7th WAMIT body about the global y-axis at the 7th WAMT body reference point; 
HydroDyn['B7HdSMzi']          = False     # (N-m); Hydrostatic moment from the 7th WAMIT body about the global z-axis at the 7th WAMT body reference point; 
HydroDyn['B7RdtFxi']          = False     # (N); Wave-radiation force at the 7th WAMIT body along the global x-axis; 
HydroDyn['B7RdtFyi']          = False     # (N); Wave-radiation force at the 7th WAMIT body along the global y-axis; 
HydroDyn['B7RdtFzi']          = False     # (N); Wave-radiation force at the 7th WAMIT body along the global z-axis; 
HydroDyn['B7RdtMxi']          = False     # (N-m); Wave-radiation moment at the 7th WAMIT body about the global x-axis at the 7th WAMIT body's reference point; 
HydroDyn['B7RdtMyi']          = False     # (N-m); Wave-radiation moment at the 7th WAMIT body about the global y-axis at the 7th WAMIT body's reference point; 
HydroDyn['B7RdtMzi']          = False     # (N-m); Wave-radiation moment at the 7th WAMIT body about the global z-axis at the 7th WAMIT body's reference point; 
HydroDyn['B8AddFxi']          = False     # (N); Force along the global x-axis due to additional preload, stiffness, and damping of the 8th WAMIT body ; 
HydroDyn['B8AddFyi']          = False     # (N); Force along the global y-axis due to additional preload, stiffness, and damping of the 8th WAMIT body ; 
HydroDyn['B8AddFzi']          = False     # (N); Force along the global z-axis due to additional preload, stiffness, and damping of the 8th WAMIT body ; 
HydroDyn['B8AddMxi']          = False     # (N-m); Moment about the global x-axis at of the 8th WAMIT body's reference point due to additional preload, stiffness, and damping ; 
HydroDyn['B8AddMyi']          = False     # (N-m); Moment about the global y-axis at of the 8th WAMIT body's reference point due to additional preload, stiffness, and damping ; 
HydroDyn['B8AddMzi']          = False     # (N-m); Moment about the global z-axis at of the 8th WAMIT body's reference point due to additional preload, stiffness, and damping ; 
HydroDyn['B8WvsF1xi']         = False     # (N); First-order wave-excitation force at the 8th WAMIT body  from diffraction  along the global x-axis; 
HydroDyn['B8WvsF1yi']         = False     # (N); First-order wave-excitation force at the 8th WAMIT body  from diffraction  along the global y-axis; 
HydroDyn['B8WvsF1zi']         = False     # (N); First-order wave-excitation force at the 8th WAMIT body  from diffraction  along the global z-axis; 
HydroDyn['B8WvsM1xi']         = False     # (N-m); First-order wave-excitation moment at the 8th WAMIT body reference point  from diffraction  about the global x-axis; 
HydroDyn['B8WvsM1yi']         = False     # (N-m); First-order wave-excitation moment at the 8th WAMIT body reference point  from diffraction  about the global y-axis; 
HydroDyn['B8WvsM1zi']         = False     # (N-m); First-order wave-excitation moment at the 8th WAMIT body reference point  from diffraction  about the global z-axis; 
HydroDyn['B8WvsFxi']          = False     # (N); Total (first-order plus second-order) wave-excitation force at the 8th WAMIT body  from diffraction  along the global x-axis; 
HydroDyn['B8WvsFyi']          = False     # (N); Total (first-order plus second-order) wave-excitation force at the 8th WAMIT body  from diffraction  along the global y-axis; 
HydroDyn['B8WvsFzi']          = False     # (N); Total (first-order plus second-order) wave-excitation force at the 8th WAMIT body  from diffraction  along the global z-axis; 
HydroDyn['B8WvsMxi']          = False     # (N-m); Total (first-order plus second-order) wave-excitation moment at the 8th WAMIT body reference point  from diffraction  about the global x-axis; 
HydroDyn['B8WvsMyi']          = False     # (N-m); Total (first-order plus second-order) wave-excitation moment at the 8th WAMIT body reference point  from diffraction  about the global y-axis; 
HydroDyn['B8WvsMzi']          = False     # (N-m); Total (first-order plus second-order) wave-excitation moment at the 8th WAMIT body reference point  from diffraction  about the global z-axis; 
HydroDyn['B8HdSFxi']          = False     # (N); Hydrostatic force from the 8th WAMIT body along the global x-axis; 
HydroDyn['B8HdSFyi']          = False     # (N); Hydrostatic force from the 8th WAMIT body along the global y-axis; 
HydroDyn['B8HdSFzi']          = False     # (N); Hydrostatic force from the 8th WAMIT body along the global z-axis; 
HydroDyn['B8HdSMxi']          = False     # (N-m); Hydrostatic moment from the 8th WAMIT body about the global x-axis at the 8th WAMT body reference point; 
HydroDyn['B8HdSMyi']          = False     # (N-m); Hydrostatic moment from the 8th WAMIT body about the global y-axis at the 8th WAMT body reference point; 
HydroDyn['B8HdSMzi']          = False     # (N-m); Hydrostatic moment from the 8th WAMIT body about the global z-axis at the 8th WAMT body reference point; 
HydroDyn['B8RdtFxi']          = False     # (N); Wave-radiation force at the 8th WAMIT body along the global x-axis; 
HydroDyn['B8RdtFyi']          = False     # (N); Wave-radiation force at the 8th WAMIT body along the global y-axis; 
HydroDyn['B8RdtFzi']          = False     # (N); Wave-radiation force at the 8th WAMIT body along the global z-axis; 
HydroDyn['B8RdtMxi']          = False     # (N-m); Wave-radiation moment at the 8th WAMIT body about the global x-axis at the 8th WAMIT body's reference point; 
HydroDyn['B8RdtMyi']          = False     # (N-m); Wave-radiation moment at the 8th WAMIT body about the global y-axis at the 8th WAMIT body's reference point; 
HydroDyn['B8RdtMzi']          = False     # (N-m); Wave-radiation moment at the 8th WAMIT body about the global z-axis at the 8th WAMIT body's reference point; 
HydroDyn['B9AddFxi']          = False     # (N); Force along the global x-axis due to additional preload, stiffness, and damping of the 9th WAMIT body ; 
HydroDyn['B9AddFyi']          = False     # (N); Force along the global y-axis due to additional preload, stiffness, and damping of the 9th WAMIT body ; 
HydroDyn['B9AddFzi']          = False     # (N); Force along the global z-axis due to additional preload, stiffness, and damping of the 9th WAMIT body ; 
HydroDyn['B9AddMxi']          = False     # (N-m); Moment about the global x-axis at of the 9th WAMIT body's reference point due to additional preload, stiffness, and damping ; 
HydroDyn['B9AddMyi']          = False     # (N-m); Moment about the global y-axis at of the 9th WAMIT body's reference point due to additional preload, stiffness, and damping ; 
HydroDyn['B9AddMzi']          = False     # (N-m); Moment about the global z-axis at of the 9th WAMIT body's reference point due to additional preload, stiffness, and damping ; 
HydroDyn['B9WvsF1xi']         = False     # (N); First-order wave-excitation force at the 9th WAMIT body  from diffraction  along the global x-axis; 
HydroDyn['B9WvsF1yi']         = False     # (N); First-order wave-excitation force at the 9th WAMIT body  from diffraction  along the global y-axis; 
HydroDyn['B9WvsF1zi']         = False     # (N); First-order wave-excitation force at the 9th WAMIT body  from diffraction  along the global z-axis; 
HydroDyn['B9WvsM1xi']         = False     # (N-m); First-order wave-excitation moment at the 9th WAMIT body reference point  from diffraction  about the global x-axis; 
HydroDyn['B9WvsM1yi']         = False     # (N-m); First-order wave-excitation moment at the 9th WAMIT body reference point  from diffraction  about the global y-axis; 
HydroDyn['B9WvsM1zi']         = False     # (N-m); First-order wave-excitation moment at the 9th WAMIT body reference point  from diffraction  about the global z-axis; 
HydroDyn['B9WvsFxi']          = False     # (N); Total (first-order plus second-order) wave-excitation force at the 9th WAMIT body  from diffraction  along the global x-axis; 
HydroDyn['B9WvsFyi']          = False     # (N); Total (first-order plus second-order) wave-excitation force at the 9th WAMIT body  from diffraction  along the global y-axis; 
HydroDyn['B9WvsFzi']          = False     # (N); Total (first-order plus second-order) wave-excitation force at the 9th WAMIT body  from diffraction  along the global z-axis; 
HydroDyn['B9WvsMxi']          = False     # (N-m); Total (first-order plus second-order) wave-excitation moment at the 9th WAMIT body reference point  from diffraction  about the global x-axis; 
HydroDyn['B9WvsMyi']          = False     # (N-m); Total (first-order plus second-order) wave-excitation moment at the 9th WAMIT body reference point  from diffraction  about the global y-axis; 
HydroDyn['B9WvsMzi']          = False     # (N-m); Total (first-order plus second-order) wave-excitation moment at the 9th WAMIT body reference point  from diffraction  about the global z-axis; 
HydroDyn['B9HdSFxi']          = False     # (N); Hydrostatic force from the 9th WAMIT body along the global x-axis; 
HydroDyn['B9HdSFyi']          = False     # (N); Hydrostatic force from the 9th WAMIT body along the global y-axis; 
HydroDyn['B9HdSFzi']          = False     # (N); Hydrostatic force from the 9th WAMIT body along the global z-axis; 
HydroDyn['B9HdSMxi']          = False     # (N-m); Hydrostatic moment from the 9th WAMIT body about the global x-axis at the 9th WAMT body reference point; 
HydroDyn['B9HdSMyi']          = False     # (N-m); Hydrostatic moment from the 9th WAMIT body about the global y-axis at the 9th WAMT body reference point; 
HydroDyn['B9HdSMzi']          = False     # (N-m); Hydrostatic moment from the 9th WAMIT body about the global z-axis at the 9th WAMT body reference point; 
HydroDyn['B9RdtFxi']          = False     # (N); Wave-radiation force at the 9th WAMIT body along the global x-axis; 
HydroDyn['B9RdtFyi']          = False     # (N); Wave-radiation force at the 9th WAMIT body along the global y-axis; 
HydroDyn['B9RdtFzi']          = False     # (N); Wave-radiation force at the 9th WAMIT body along the global z-axis; 
HydroDyn['B9RdtMxi']          = False     # (N-m); Wave-radiation moment at the 9th WAMIT body about the global x-axis at the 9th WAMIT body's reference point; 
HydroDyn['B9RdtMyi']          = False     # (N-m); Wave-radiation moment at the 9th WAMIT body about the global y-axis at the 9th WAMIT body's reference point; 
HydroDyn['B9RdtMzi']          = False     # (N-m); Wave-radiation moment at the 9th WAMIT body about the global z-axis at the 9th WAMIT body's reference point; 
HydroDyn['B1WvsF2xi']         = False     # (N); Second-order wave-excitation force  at the 1st WAMIT body from diffraction  along the global x-axis; 
HydroDyn['B1WvsF2yi']         = False     # (N); Second-order wave-excitation force  at the 1st WAMIT body from diffraction  along the global y-axis; 
HydroDyn['B1WvsF2zi']         = False     # (N); Second-order wave-excitation force  at the 1st WAMIT body from diffraction  along the global z-axis; 
HydroDyn['B1WvsM2xi']         = False     # (N-m); Second-order wave-excitation moment at the 1st WAMIT body reference point  from diffraction  about the global x-axis; 
HydroDyn['B1WvsM2yi']         = False     # (N-m); Second-order wave-excitation moment at the 1st WAMIT body reference point  from diffraction  about the global y-axis; 
HydroDyn['B1WvsM2zi']         = False     # (N-m); Second-order wave-excitation moment at the 1st WAMIT body reference point  from diffraction  about the global z-axis; 
HydroDyn['B2WvsF2xi']         = False     # (N); Second-order wave-excitation force  at the 2nd WAMIT body from diffraction  along the global x-axis; 
HydroDyn['B2WvsF2yi']         = False     # (N); Second-order wave-excitation force  at the 2nd WAMIT body from diffraction  along the global y-axis; 
HydroDyn['B2WvsF2zi']         = False     # (N); Second-order wave-excitation force  at the 2nd WAMIT body from diffraction  along the global z-axis; 
HydroDyn['B2WvsM2xi']         = False     # (N-m); Second-order wave-excitation moment at the 2nd WAMIT body reference point  from diffraction  about the global x-axis; 
HydroDyn['B2WvsM2yi']         = False     # (N-m); Second-order wave-excitation moment at the 2nd WAMIT body reference point  from diffraction  about the global y-axis; 
HydroDyn['B2WvsM2zi']         = False     # (N-m); Second-order wave-excitation moment at the 2nd WAMIT body reference point  from diffraction  about the global z-axis; 
HydroDyn['B3WvsF2xi']         = False     # (N); Second-order wave-excitation force  at the 3rd WAMIT body from diffraction  along the global x-axis; 
HydroDyn['B3WvsF2yi']         = False     # (N); Second-order wave-excitation force  at the 3rd WAMIT body from diffraction  along the global y-axis; 
HydroDyn['B3WvsF2zi']         = False     # (N); Second-order wave-excitation force  at the 3rd WAMIT body from diffraction  along the global z-axis; 
HydroDyn['B3WvsM2xi']         = False     # (N-m); Second-order wave-excitation moment at the 3rd WAMIT body reference point  from diffraction  about the global x-axis; 
HydroDyn['B3WvsM2yi']         = False     # (N-m); Second-order wave-excitation moment at the 3rd WAMIT body reference point  from diffraction  about the global y-axis; 
HydroDyn['B3WvsM2zi']         = False     # (N-m); Second-order wave-excitation moment at the 3rd WAMIT body reference point  from diffraction  about the global z-axis; 
HydroDyn['B4WvsF2xi']         = False     # (N); Second-order wave-excitation force  at the 4th WAMIT body from diffraction  along the global x-axis; 
HydroDyn['B4WvsF2yi']         = False     # (N); Second-order wave-excitation force  at the 4th WAMIT body from diffraction  along the global y-axis; 
HydroDyn['B4WvsF2zi']         = False     # (N); Second-order wave-excitation force  at the 4th WAMIT body from diffraction  along the global z-axis; 
HydroDyn['B4WvsM2xi']         = False     # (N-m); Second-order wave-excitation moment at the 4th WAMIT body reference point  from diffraction  about the global x-axis; 
HydroDyn['B4WvsM2yi']         = False     # (N-m); Second-order wave-excitation moment at the 4th WAMIT body reference point  from diffraction  about the global y-axis; 
HydroDyn['B4WvsM2zi']         = False     # (N-m); Second-order wave-excitation moment at the 4th WAMIT body reference point  from diffraction  about the global z-axis; 
HydroDyn['B5WvsF2xi']         = False     # (N); Second-order wave-excitation force  at the 5th WAMIT body from diffraction  along the global x-axis; 
HydroDyn['B5WvsF2yi']         = False     # (N); Second-order wave-excitation force  at the 5th WAMIT body from diffraction  along the global y-axis; 
HydroDyn['B5WvsF2zi']         = False     # (N); Second-order wave-excitation force  at the 5th WAMIT body from diffraction  along the global z-axis; 
HydroDyn['B5WvsM2xi']         = False     # (N-m); Second-order wave-excitation moment at the 5th WAMIT body reference point  from diffraction  about the global x-axis; 
HydroDyn['B5WvsM2yi']         = False     # (N-m); Second-order wave-excitation moment at the 5th WAMIT body reference point  from diffraction  about the global y-axis; 
HydroDyn['B5WvsM2zi']         = False     # (N-m); Second-order wave-excitation moment at the 5th WAMIT body reference point  from diffraction  about the global z-axis; 
HydroDyn['B6WvsF2xi']         = False     # (N); Second-order wave-excitation force  at the 6th WAMIT body from diffraction  along the global x-axis; 
HydroDyn['B6WvsF2yi']         = False     # (N); Second-order wave-excitation force  at the 6th WAMIT body from diffraction  along the global y-axis; 
HydroDyn['B6WvsF2zi']         = False     # (N); Second-order wave-excitation force  at the 6th WAMIT body from diffraction  along the global z-axis; 
HydroDyn['B6WvsM2xi']         = False     # (N-m); Second-order wave-excitation moment at the 6th WAMIT body reference point  from diffraction  about the global x-axis; 
HydroDyn['B6WvsM2yi']         = False     # (N-m); Second-order wave-excitation moment at the 6th WAMIT body reference point  from diffraction  about the global y-axis; 
HydroDyn['B6WvsM2zi']         = False     # (N-m); Second-order wave-excitation moment at the 6th WAMIT body reference point  from diffraction  about the global z-axis; 
HydroDyn['B7WvsF2xi']         = False     # (N); Second-order wave-excitation force  at the 7th WAMIT body from diffraction  along the global x-axis; 
HydroDyn['B7WvsF2yi']         = False     # (N); Second-order wave-excitation force  at the 7th WAMIT body from diffraction  along the global y-axis; 
HydroDyn['B7WvsF2zi']         = False     # (N); Second-order wave-excitation force  at the 7th WAMIT body from diffraction  along the global z-axis; 
HydroDyn['B7WvsM2xi']         = False     # (N-m); Second-order wave-excitation moment at the 7th WAMIT body reference point  from diffraction  about the global x-axis; 
HydroDyn['B7WvsM2yi']         = False     # (N-m); Second-order wave-excitation moment at the 7th WAMIT body reference point  from diffraction  about the global y-axis; 
HydroDyn['B7WvsM2zi']         = False     # (N-m); Second-order wave-excitation moment at the 7th WAMIT body reference point  from diffraction  about the global z-axis; 
HydroDyn['B8WvsF2xi']         = False     # (N); Second-order wave-excitation force  at the 8th WAMIT body from diffraction  along the global x-axis; 
HydroDyn['B8WvsF2yi']         = False     # (N); Second-order wave-excitation force  at the 8th WAMIT body from diffraction  along the global y-axis; 
HydroDyn['B8WvsF2zi']         = False     # (N); Second-order wave-excitation force  at the 8th WAMIT body from diffraction  along the global z-axis; 
HydroDyn['B8WvsM2xi']         = False     # (N-m); Second-order wave-excitation moment at the 8th WAMIT body reference point  from diffraction  about the global x-axis; 
HydroDyn['B8WvsM2yi']         = False     # (N-m); Second-order wave-excitation moment at the 8th WAMIT body reference point  from diffraction  about the global y-axis; 
HydroDyn['B8WvsM2zi']         = False     # (N-m); Second-order wave-excitation moment at the 8th WAMIT body reference point  from diffraction  about the global z-axis; 
HydroDyn['B9WvsF2xi']         = False     # (N); Second-order wave-excitation force  at the 9th WAMIT body from diffraction  along the global x-axis; 
HydroDyn['B9WvsF2yi']         = False     # (N); Second-order wave-excitation force  at the 9th WAMIT body from diffraction  along the global y-axis; 
HydroDyn['B9WvsF2zi']         = False     # (N); Second-order wave-excitation force  at the 9th WAMIT body from diffraction  along the global z-axis; 
HydroDyn['B9WvsM2xi']         = False     # (N-m); Second-order wave-excitation moment at the 9th WAMIT body reference point  from diffraction  about the global x-axis; 
HydroDyn['B9WvsM2yi']         = False     # (N-m); Second-order wave-excitation moment at the 9th WAMIT body reference point  from diffraction  about the global y-axis; 
HydroDyn['B9WvsM2zi']         = False     # (N-m); Second-order wave-excitation moment at the 9th WAMIT body reference point  from diffraction  about the global z-axis; 


""" Morison """
Morison = {}

# Member-level Wave Kinematics 
Morison['M1N1Axi']            = False     # (m/s^2); fluid acceleration; 
Morison['M1N2Axi']            = False     # (m/s^2); ; 
Morison['M1N3Axi']            = False     # (m/s^2); ; 
Morison['M1N4Axi']            = False     # (m/s^2); ; 
Morison['M1N5Axi']            = False     # (m/s^2); ; 
Morison['M1N6Axi']            = False     # (m/s^2); ; 
Morison['M1N7Axi']            = False     # (m/s^2); ; 
Morison['M1N8Axi']            = False     # (m/s^2); ; 
Morison['M1N9Axi']            = False     # (m/s^2); ; 
Morison['M2N1Axi']            = False     # (m/s^2); ; 
Morison['M2N2Axi']            = False     # (m/s^2); ; 
Morison['M2N3Axi']            = False     # (m/s^2); ; 
Morison['M2N4Axi']            = False     # (m/s^2); ; 
Morison['M2N5Axi']            = False     # (m/s^2); ; 
Morison['M2N6Axi']            = False     # (m/s^2); ; 
Morison['M2N7Axi']            = False     # (m/s^2); ; 
Morison['M2N8Axi']            = False     # (m/s^2); ; 
Morison['M2N9Axi']            = False     # (m/s^2); ; 
Morison['M3N1Axi']            = False     # (m/s^2); ; 
Morison['M3N2Axi']            = False     # (m/s^2); ; 
Morison['M3N3Axi']            = False     # (m/s^2); ; 
Morison['M3N4Axi']            = False     # (m/s^2); ; 
Morison['M3N5Axi']            = False     # (m/s^2); ; 
Morison['M3N6Axi']            = False     # (m/s^2); ; 
Morison['M3N7Axi']            = False     # (m/s^2); ; 
Morison['M3N8Axi']            = False     # (m/s^2); ; 
Morison['M3N9Axi']            = False     # (m/s^2); ; 
Morison['M4N1Axi']            = False     # (m/s^2); ; 
Morison['M4N2Axi']            = False     # (m/s^2); ; 
Morison['M4N3Axi']            = False     # (m/s^2); ; 
Morison['M4N4Axi']            = False     # (m/s^2); ; 
Morison['M4N5Axi']            = False     # (m/s^2); ; 
Morison['M4N6Axi']            = False     # (m/s^2); ; 
Morison['M4N7Axi']            = False     # (m/s^2); ; 
Morison['M4N8Axi']            = False     # (m/s^2); ; 
Morison['M4N9Axi']            = False     # (m/s^2); ; 
Morison['M5N1Axi']            = False     # (m/s^2); ; 
Morison['M5N2Axi']            = False     # (m/s^2); ; 
Morison['M5N3Axi']            = False     # (m/s^2); ; 
Morison['M5N4Axi']            = False     # (m/s^2); ; 
Morison['M5N5Axi']            = False     # (m/s^2); ; 
Morison['M5N6Axi']            = False     # (m/s^2); ; 
Morison['M5N7Axi']            = False     # (m/s^2); ; 
Morison['M5N8Axi']            = False     # (m/s^2); ; 
Morison['M5N9Axi']            = False     # (m/s^2); ; 
Morison['M6N1Axi']            = False     # (m/s^2); ; 
Morison['M6N2Axi']            = False     # (m/s^2); ; 
Morison['M6N3Axi']            = False     # (m/s^2); ; 
Morison['M6N4Axi']            = False     # (m/s^2); ; 
Morison['M6N5Axi']            = False     # (m/s^2); ; 
Morison['M6N6Axi']            = False     # (m/s^2); ; 
Morison['M6N7Axi']            = False     # (m/s^2); ; 
Morison['M6N8Axi']            = False     # (m/s^2); ; 
Morison['M6N9Axi']            = False     # (m/s^2); ; 
Morison['M7N1Axi']            = False     # (m/s^2); ; 
Morison['M7N2Axi']            = False     # (m/s^2); ; 
Morison['M7N3Axi']            = False     # (m/s^2); ; 
Morison['M7N4Axi']            = False     # (m/s^2); ; 
Morison['M7N5Axi']            = False     # (m/s^2); ; 
Morison['M7N6Axi']            = False     # (m/s^2); ; 
Morison['M7N7Axi']            = False     # (m/s^2); ; 
Morison['M7N8Axi']            = False     # (m/s^2); ; 
Morison['M7N9Axi']            = False     # (m/s^2); ; 
Morison['M8N1Axi']            = False     # (m/s^2); ; 
Morison['M8N2Axi']            = False     # (m/s^2); ; 
Morison['M8N3Axi']            = False     # (m/s^2); ; 
Morison['M8N4Axi']            = False     # (m/s^2); ; 
Morison['M8N5Axi']            = False     # (m/s^2); ; 
Morison['M8N6Axi']            = False     # (m/s^2); ; 
Morison['M8N7Axi']            = False     # (m/s^2); ; 
Morison['M8N8Axi']            = False     # (m/s^2); ; 
Morison['M8N9Axi']            = False     # (m/s^2); ; 
Morison['M9N1Axi']            = False     # (m/s^2); ; 
Morison['M9N2Axi']            = False     # (m/s^2); ; 
Morison['M9N3Axi']            = False     # (m/s^2); ; 
Morison['M9N4Axi']            = False     # (m/s^2); ; 
Morison['M9N5Axi']            = False     # (m/s^2); ; 
Morison['M9N6Axi']            = False     # (m/s^2); ; 
Morison['M9N7Axi']            = False     # (m/s^2); ; 
Morison['M9N8Axi']            = False     # (m/s^2); ; 
Morison['M9N9Axi']            = False     # (m/s^2); ; 
Morison['M1N1Ayi']            = False     # (m/s^2); ; 
Morison['M1N2Ayi']            = False     # (m/s^2); ; 
Morison['M1N3Ayi']            = False     # (m/s^2); ; 
Morison['M1N4Ayi']            = False     # (m/s^2); ; 
Morison['M1N5Ayi']            = False     # (m/s^2); ; 
Morison['M1N6Ayi']            = False     # (m/s^2); ; 
Morison['M1N7Ayi']            = False     # (m/s^2); ; 
Morison['M1N8Ayi']            = False     # (m/s^2); ; 
Morison['M1N9Ayi']            = False     # (m/s^2); ; 
Morison['M2N1Ayi']            = False     # (m/s^2); ; 
Morison['M2N2Ayi']            = False     # (m/s^2); ; 
Morison['M2N3Ayi']            = False     # (m/s^2); ; 
Morison['M2N4Ayi']            = False     # (m/s^2); ; 
Morison['M2N5Ayi']            = False     # (m/s^2); ; 
Morison['M2N6Ayi']            = False     # (m/s^2); ; 
Morison['M2N7Ayi']            = False     # (m/s^2); ; 
Morison['M2N8Ayi']            = False     # (m/s^2); ; 
Morison['M2N9Ayi']            = False     # (m/s^2); ; 
Morison['M3N1Ayi']            = False     # (m/s^2); ; 
Morison['M3N2Ayi']            = False     # (m/s^2); ; 
Morison['M3N3Ayi']            = False     # (m/s^2); ; 
Morison['M3N4Ayi']            = False     # (m/s^2); ; 
Morison['M3N5Ayi']            = False     # (m/s^2); ; 
Morison['M3N6Ayi']            = False     # (m/s^2); ; 
Morison['M3N7Ayi']            = False     # (m/s^2); ; 
Morison['M3N8Ayi']            = False     # (m/s^2); ; 
Morison['M3N9Ayi']            = False     # (m/s^2); ; 
Morison['M4N1Ayi']            = False     # (m/s^2); ; 
Morison['M4N2Ayi']            = False     # (m/s^2); ; 
Morison['M4N3Ayi']            = False     # (m/s^2); ; 
Morison['M4N4Ayi']            = False     # (m/s^2); ; 
Morison['M4N5Ayi']            = False     # (m/s^2); ; 
Morison['M4N6Ayi']            = False     # (m/s^2); ; 
Morison['M4N7Ayi']            = False     # (m/s^2); ; 
Morison['M4N8Ayi']            = False     # (m/s^2); ; 
Morison['M4N9Ayi']            = False     # (m/s^2); ; 
Morison['M5N1Ayi']            = False     # (m/s^2); ; 
Morison['M5N2Ayi']            = False     # (m/s^2); ; 
Morison['M5N3Ayi']            = False     # (m/s^2); ; 
Morison['M5N4Ayi']            = False     # (m/s^2); ; 
Morison['M5N5Ayi']            = False     # (m/s^2); ; 
Morison['M5N6Ayi']            = False     # (m/s^2); ; 
Morison['M5N7Ayi']            = False     # (m/s^2); ; 
Morison['M5N8Ayi']            = False     # (m/s^2); ; 
Morison['M5N9Ayi']            = False     # (m/s^2); ; 
Morison['M6N1Ayi']            = False     # (m/s^2); ; 
Morison['M6N2Ayi']            = False     # (m/s^2); ; 
Morison['M6N3Ayi']            = False     # (m/s^2); ; 
Morison['M6N4Ayi']            = False     # (m/s^2); ; 
Morison['M6N5Ayi']            = False     # (m/s^2); ; 
Morison['M6N6Ayi']            = False     # (m/s^2); ; 
Morison['M6N7Ayi']            = False     # (m/s^2); ; 
Morison['M6N8Ayi']            = False     # (m/s^2); ; 
Morison['M6N9Ayi']            = False     # (m/s^2); ; 
Morison['M7N1Ayi']            = False     # (m/s^2); ; 
Morison['M7N2Ayi']            = False     # (m/s^2); ; 
Morison['M7N3Ayi']            = False     # (m/s^2); ; 
Morison['M7N4Ayi']            = False     # (m/s^2); ; 
Morison['M7N5Ayi']            = False     # (m/s^2); ; 
Morison['M7N6Ayi']            = False     # (m/s^2); ; 
Morison['M7N7Ayi']            = False     # (m/s^2); ; 
Morison['M7N8Ayi']            = False     # (m/s^2); ; 
Morison['M7N9Ayi']            = False     # (m/s^2); ; 
Morison['M8N1Ayi']            = False     # (m/s^2); ; 
Morison['M8N2Ayi']            = False     # (m/s^2); ; 
Morison['M8N3Ayi']            = False     # (m/s^2); ; 
Morison['M8N4Ayi']            = False     # (m/s^2); ; 
Morison['M8N5Ayi']            = False     # (m/s^2); ; 
Morison['M8N6Ayi']            = False     # (m/s^2); ; 
Morison['M8N7Ayi']            = False     # (m/s^2); ; 
Morison['M8N8Ayi']            = False     # (m/s^2); ; 
Morison['M8N9Ayi']            = False     # (m/s^2); ; 
Morison['M9N1Ayi']            = False     # (m/s^2); ; 
Morison['M9N2Ayi']            = False     # (m/s^2); ; 
Morison['M9N3Ayi']            = False     # (m/s^2); ; 
Morison['M9N4Ayi']            = False     # (m/s^2); ; 
Morison['M9N5Ayi']            = False     # (m/s^2); ; 
Morison['M9N6Ayi']            = False     # (m/s^2); ; 
Morison['M9N7Ayi']            = False     # (m/s^2); ; 
Morison['M9N8Ayi']            = False     # (m/s^2); ; 
Morison['M9N9Ayi']            = False     # (m/s^2); ; 
Morison['M1N1Azi']            = False     # (m/s^2); ; 
Morison['M1N2Azi']            = False     # (m/s^2); ; 
Morison['M1N3Azi']            = False     # (m/s^2); ; 
Morison['M1N4Azi']            = False     # (m/s^2); ; 
Morison['M1N5Azi']            = False     # (m/s^2); ; 
Morison['M1N6Azi']            = False     # (m/s^2); ; 
Morison['M1N7Azi']            = False     # (m/s^2); ; 
Morison['M1N8Azi']            = False     # (m/s^2); ; 
Morison['M1N9Azi']            = False     # (m/s^2); ; 
Morison['M2N1Azi']            = False     # (m/s^2); ; 
Morison['M2N2Azi']            = False     # (m/s^2); ; 
Morison['M2N3Azi']            = False     # (m/s^2); ; 
Morison['M2N4Azi']            = False     # (m/s^2); ; 
Morison['M2N5Azi']            = False     # (m/s^2); ; 
Morison['M2N6Azi']            = False     # (m/s^2); ; 
Morison['M2N7Azi']            = False     # (m/s^2); ; 
Morison['M2N8Azi']            = False     # (m/s^2); ; 
Morison['M2N9Azi']            = False     # (m/s^2); ; 
Morison['M3N1Azi']            = False     # (m/s^2); ; 
Morison['M3N2Azi']            = False     # (m/s^2); ; 
Morison['M3N3Azi']            = False     # (m/s^2); ; 
Morison['M3N4Azi']            = False     # (m/s^2); ; 
Morison['M3N5Azi']            = False     # (m/s^2); ; 
Morison['M3N6Azi']            = False     # (m/s^2); ; 
Morison['M3N7Azi']            = False     # (m/s^2); ; 
Morison['M3N8Azi']            = False     # (m/s^2); ; 
Morison['M3N9Azi']            = False     # (m/s^2); ; 
Morison['M4N1Azi']            = False     # (m/s^2); ; 
Morison['M4N2Azi']            = False     # (m/s^2); ; 
Morison['M4N3Azi']            = False     # (m/s^2); ; 
Morison['M4N4Azi']            = False     # (m/s^2); ; 
Morison['M4N5Azi']            = False     # (m/s^2); ; 
Morison['M4N6Azi']            = False     # (m/s^2); ; 
Morison['M4N7Azi']            = False     # (m/s^2); ; 
Morison['M4N8Azi']            = False     # (m/s^2); ; 
Morison['M4N9Azi']            = False     # (m/s^2); ; 
Morison['M5N1Azi']            = False     # (m/s^2); ; 
Morison['M5N2Azi']            = False     # (m/s^2); ; 
Morison['M5N3Azi']            = False     # (m/s^2); ; 
Morison['M5N4Azi']            = False     # (m/s^2); ; 
Morison['M5N5Azi']            = False     # (m/s^2); ; 
Morison['M5N6Azi']            = False     # (m/s^2); ; 
Morison['M5N7Azi']            = False     # (m/s^2); ; 
Morison['M5N8Azi']            = False     # (m/s^2); ; 
Morison['M5N9Azi']            = False     # (m/s^2); ; 
Morison['M6N1Azi']            = False     # (m/s^2); ; 
Morison['M6N2Azi']            = False     # (m/s^2); ; 
Morison['M6N3Azi']            = False     # (m/s^2); ; 
Morison['M6N4Azi']            = False     # (m/s^2); ; 
Morison['M6N5Azi']            = False     # (m/s^2); ; 
Morison['M6N6Azi']            = False     # (m/s^2); ; 
Morison['M6N7Azi']            = False     # (m/s^2); ; 
Morison['M6N8Azi']            = False     # (m/s^2); ; 
Morison['M6N9Azi']            = False     # (m/s^2); ; 
Morison['M7N1Azi']            = False     # (m/s^2); ; 
Morison['M7N2Azi']            = False     # (m/s^2); ; 
Morison['M7N3Azi']            = False     # (m/s^2); ; 
Morison['M7N4Azi']            = False     # (m/s^2); ; 
Morison['M7N5Azi']            = False     # (m/s^2); ; 
Morison['M7N6Azi']            = False     # (m/s^2); ; 
Morison['M7N7Azi']            = False     # (m/s^2); ; 
Morison['M7N8Azi']            = False     # (m/s^2); ; 
Morison['M7N9Azi']            = False     # (m/s^2); ; 
Morison['M8N1Azi']            = False     # (m/s^2); ; 
Morison['M8N2Azi']            = False     # (m/s^2); ; 
Morison['M8N3Azi']            = False     # (m/s^2); ; 
Morison['M8N4Azi']            = False     # (m/s^2); ; 
Morison['M8N5Azi']            = False     # (m/s^2); ; 
Morison['M8N6Azi']            = False     # (m/s^2); ; 
Morison['M8N7Azi']            = False     # (m/s^2); ; 
Morison['M8N8Azi']            = False     # (m/s^2); ; 
Morison['M8N9Azi']            = False     # (m/s^2); ; 
Morison['M9N1Azi']            = False     # (m/s^2); ; 
Morison['M9N2Azi']            = False     # (m/s^2); ; 
Morison['M9N3Azi']            = False     # (m/s^2); ; 
Morison['M9N4Azi']            = False     # (m/s^2); ; 
Morison['M9N5Azi']            = False     # (m/s^2); ; 
Morison['M9N6Azi']            = False     # (m/s^2); ; 
Morison['M9N7Azi']            = False     # (m/s^2); ; 
Morison['M9N8Azi']            = False     # (m/s^2); ; 
Morison['M9N9Azi']            = False     # (m/s^2); ; 
Morison['M1N1Vxi']            = False     # (m/s); fluid velocity; 
Morison['M1N2Vxi']            = False     # (m/s); ; 
Morison['M1N3Vxi']            = False     # (m/s); ; 
Morison['M1N4Vxi']            = False     # (m/s); ; 
Morison['M1N5Vxi']            = False     # (m/s); ; 
Morison['M1N6Vxi']            = False     # (m/s); ; 
Morison['M1N7Vxi']            = False     # (m/s); ; 
Morison['M1N8Vxi']            = False     # (m/s); ; 
Morison['M1N9Vxi']            = False     # (m/s); ; 
Morison['M2N1Vxi']            = False     # (m/s); ; 
Morison['M2N2Vxi']            = False     # (m/s); ; 
Morison['M2N3Vxi']            = False     # (m/s); ; 
Morison['M2N4Vxi']            = False     # (m/s); ; 
Morison['M2N5Vxi']            = False     # (m/s); ; 
Morison['M2N6Vxi']            = False     # (m/s); ; 
Morison['M2N7Vxi']            = False     # (m/s); ; 
Morison['M2N8Vxi']            = False     # (m/s); ; 
Morison['M2N9Vxi']            = False     # (m/s); ; 
Morison['M3N1Vxi']            = False     # (m/s); ; 
Morison['M3N2Vxi']            = False     # (m/s); ; 
Morison['M3N3Vxi']            = False     # (m/s); ; 
Morison['M3N4Vxi']            = False     # (m/s); ; 
Morison['M3N5Vxi']            = False     # (m/s); ; 
Morison['M3N6Vxi']            = False     # (m/s); ; 
Morison['M3N7Vxi']            = False     # (m/s); ; 
Morison['M3N8Vxi']            = False     # (m/s); ; 
Morison['M3N9Vxi']            = False     # (m/s); ; 
Morison['M4N1Vxi']            = False     # (m/s); ; 
Morison['M4N2Vxi']            = False     # (m/s); ; 
Morison['M4N3Vxi']            = False     # (m/s); ; 
Morison['M4N4Vxi']            = False     # (m/s); ; 
Morison['M4N5Vxi']            = False     # (m/s); ; 
Morison['M4N6Vxi']            = False     # (m/s); ; 
Morison['M4N7Vxi']            = False     # (m/s); ; 
Morison['M4N8Vxi']            = False     # (m/s); ; 
Morison['M4N9Vxi']            = False     # (m/s); ; 
Morison['M5N1Vxi']            = False     # (m/s); ; 
Morison['M5N2Vxi']            = False     # (m/s); ; 
Morison['M5N3Vxi']            = False     # (m/s); ; 
Morison['M5N4Vxi']            = False     # (m/s); ; 
Morison['M5N5Vxi']            = False     # (m/s); ; 
Morison['M5N6Vxi']            = False     # (m/s); ; 
Morison['M5N7Vxi']            = False     # (m/s); ; 
Morison['M5N8Vxi']            = False     # (m/s); ; 
Morison['M5N9Vxi']            = False     # (m/s); ; 
Morison['M6N1Vxi']            = False     # (m/s); ; 
Morison['M6N2Vxi']            = False     # (m/s); ; 
Morison['M6N3Vxi']            = False     # (m/s); ; 
Morison['M6N4Vxi']            = False     # (m/s); ; 
Morison['M6N5Vxi']            = False     # (m/s); ; 
Morison['M6N6Vxi']            = False     # (m/s); ; 
Morison['M6N7Vxi']            = False     # (m/s); ; 
Morison['M6N8Vxi']            = False     # (m/s); ; 
Morison['M6N9Vxi']            = False     # (m/s); ; 
Morison['M7N1Vxi']            = False     # (m/s); ; 
Morison['M7N2Vxi']            = False     # (m/s); ; 
Morison['M7N3Vxi']            = False     # (m/s); ; 
Morison['M7N4Vxi']            = False     # (m/s); ; 
Morison['M7N5Vxi']            = False     # (m/s); ; 
Morison['M7N6Vxi']            = False     # (m/s); ; 
Morison['M7N7Vxi']            = False     # (m/s); ; 
Morison['M7N8Vxi']            = False     # (m/s); ; 
Morison['M7N9Vxi']            = False     # (m/s); ; 
Morison['M8N1Vxi']            = False     # (m/s); ; 
Morison['M8N2Vxi']            = False     # (m/s); ; 
Morison['M8N3Vxi']            = False     # (m/s); ; 
Morison['M8N4Vxi']            = False     # (m/s); ; 
Morison['M8N5Vxi']            = False     # (m/s); ; 
Morison['M8N6Vxi']            = False     # (m/s); ; 
Morison['M8N7Vxi']            = False     # (m/s); ; 
Morison['M8N8Vxi']            = False     # (m/s); ; 
Morison['M8N9Vxi']            = False     # (m/s); ; 
Morison['M9N1Vxi']            = False     # (m/s); ; 
Morison['M9N2Vxi']            = False     # (m/s); ; 
Morison['M9N3Vxi']            = False     # (m/s); ; 
Morison['M9N4Vxi']            = False     # (m/s); ; 
Morison['M9N5Vxi']            = False     # (m/s); ; 
Morison['M9N6Vxi']            = False     # (m/s); ; 
Morison['M9N7Vxi']            = False     # (m/s); ; 
Morison['M9N8Vxi']            = False     # (m/s); ; 
Morison['M9N9Vxi']            = False     # (m/s); ; 
Morison['M1N1Vyi']            = False     # (m/s); ; 
Morison['M1N2Vyi']            = False     # (m/s); ; 
Morison['M1N3Vyi']            = False     # (m/s); ; 
Morison['M1N4Vyi']            = False     # (m/s); ; 
Morison['M1N5Vyi']            = False     # (m/s); ; 
Morison['M1N6Vyi']            = False     # (m/s); ; 
Morison['M1N7Vyi']            = False     # (m/s); ; 
Morison['M1N8Vyi']            = False     # (m/s); ; 
Morison['M1N9Vyi']            = False     # (m/s); ; 
Morison['M2N1Vyi']            = False     # (m/s); ; 
Morison['M2N2Vyi']            = False     # (m/s); ; 
Morison['M2N3Vyi']            = False     # (m/s); ; 
Morison['M2N4Vyi']            = False     # (m/s); ; 
Morison['M2N5Vyi']            = False     # (m/s); ; 
Morison['M2N6Vyi']            = False     # (m/s); ; 
Morison['M2N7Vyi']            = False     # (m/s); ; 
Morison['M2N8Vyi']            = False     # (m/s); ; 
Morison['M2N9Vyi']            = False     # (m/s); ; 
Morison['M3N1Vyi']            = False     # (m/s); ; 
Morison['M3N2Vyi']            = False     # (m/s); ; 
Morison['M3N3Vyi']            = False     # (m/s); ; 
Morison['M3N4Vyi']            = False     # (m/s); ; 
Morison['M3N5Vyi']            = False     # (m/s); ; 
Morison['M3N6Vyi']            = False     # (m/s); ; 
Morison['M3N7Vyi']            = False     # (m/s); ; 
Morison['M3N8Vyi']            = False     # (m/s); ; 
Morison['M3N9Vyi']            = False     # (m/s); ; 
Morison['M4N1Vyi']            = False     # (m/s); ; 
Morison['M4N2Vyi']            = False     # (m/s); ; 
Morison['M4N3Vyi']            = False     # (m/s); ; 
Morison['M4N4Vyi']            = False     # (m/s); ; 
Morison['M4N5Vyi']            = False     # (m/s); ; 
Morison['M4N6Vyi']            = False     # (m/s); ; 
Morison['M4N7Vyi']            = False     # (m/s); ; 
Morison['M4N8Vyi']            = False     # (m/s); ; 
Morison['M4N9Vyi']            = False     # (m/s); ; 
Morison['M5N1Vyi']            = False     # (m/s); ; 
Morison['M5N2Vyi']            = False     # (m/s); ; 
Morison['M5N3Vyi']            = False     # (m/s); ; 
Morison['M5N4Vyi']            = False     # (m/s); ; 
Morison['M5N5Vyi']            = False     # (m/s); ; 
Morison['M5N6Vyi']            = False     # (m/s); ; 
Morison['M5N7Vyi']            = False     # (m/s); ; 
Morison['M5N8Vyi']            = False     # (m/s); ; 
Morison['M5N9Vyi']            = False     # (m/s); ; 
Morison['M6N1Vyi']            = False     # (m/s); ; 
Morison['M6N2Vyi']            = False     # (m/s); ; 
Morison['M6N3Vyi']            = False     # (m/s); ; 
Morison['M6N4Vyi']            = False     # (m/s); ; 
Morison['M6N5Vyi']            = False     # (m/s); ; 
Morison['M6N6Vyi']            = False     # (m/s); ; 
Morison['M6N7Vyi']            = False     # (m/s); ; 
Morison['M6N8Vyi']            = False     # (m/s); ; 
Morison['M6N9Vyi']            = False     # (m/s); ; 
Morison['M7N1Vyi']            = False     # (m/s); ; 
Morison['M7N2Vyi']            = False     # (m/s); ; 
Morison['M7N3Vyi']            = False     # (m/s); ; 
Morison['M7N4Vyi']            = False     # (m/s); ; 
Morison['M7N5Vyi']            = False     # (m/s); ; 
Morison['M7N6Vyi']            = False     # (m/s); ; 
Morison['M7N7Vyi']            = False     # (m/s); ; 
Morison['M7N8Vyi']            = False     # (m/s); ; 
Morison['M7N9Vyi']            = False     # (m/s); ; 
Morison['M8N1Vyi']            = False     # (m/s); ; 
Morison['M8N2Vyi']            = False     # (m/s); ; 
Morison['M8N3Vyi']            = False     # (m/s); ; 
Morison['M8N4Vyi']            = False     # (m/s); ; 
Morison['M8N5Vyi']            = False     # (m/s); ; 
Morison['M8N6Vyi']            = False     # (m/s); ; 
Morison['M8N7Vyi']            = False     # (m/s); ; 
Morison['M8N8Vyi']            = False     # (m/s); ; 
Morison['M8N9Vyi']            = False     # (m/s); ; 
Morison['M9N1Vyi']            = False     # (m/s); ; 
Morison['M9N2Vyi']            = False     # (m/s); ; 
Morison['M9N3Vyi']            = False     # (m/s); ; 
Morison['M9N4Vyi']            = False     # (m/s); ; 
Morison['M9N5Vyi']            = False     # (m/s); ; 
Morison['M9N6Vyi']            = False     # (m/s); ; 
Morison['M9N7Vyi']            = False     # (m/s); ; 
Morison['M9N8Vyi']            = False     # (m/s); ; 
Morison['M9N9Vyi']            = False     # (m/s); ; 
Morison['M1N1Vzi']            = False     # (m/s); ; 
Morison['M1N2Vzi']            = False     # (m/s); ; 
Morison['M1N3Vzi']            = False     # (m/s); ; 
Morison['M1N4Vzi']            = False     # (m/s); ; 
Morison['M1N5Vzi']            = False     # (m/s); ; 
Morison['M1N6Vzi']            = False     # (m/s); ; 
Morison['M1N7Vzi']            = False     # (m/s); ; 
Morison['M1N8Vzi']            = False     # (m/s); ; 
Morison['M1N9Vzi']            = False     # (m/s); ; 
Morison['M2N1Vzi']            = False     # (m/s); ; 
Morison['M2N2Vzi']            = False     # (m/s); ; 
Morison['M2N3Vzi']            = False     # (m/s); ; 
Morison['M2N4Vzi']            = False     # (m/s); ; 
Morison['M2N5Vzi']            = False     # (m/s); ; 
Morison['M2N6Vzi']            = False     # (m/s); ; 
Morison['M2N7Vzi']            = False     # (m/s); ; 
Morison['M2N8Vzi']            = False     # (m/s); ; 
Morison['M2N9Vzi']            = False     # (m/s); ; 
Morison['M3N1Vzi']            = False     # (m/s); ; 
Morison['M3N2Vzi']            = False     # (m/s); ; 
Morison['M3N3Vzi']            = False     # (m/s); ; 
Morison['M3N4Vzi']            = False     # (m/s); ; 
Morison['M3N5Vzi']            = False     # (m/s); ; 
Morison['M3N6Vzi']            = False     # (m/s); ; 
Morison['M3N7Vzi']            = False     # (m/s); ; 
Morison['M3N8Vzi']            = False     # (m/s); ; 
Morison['M3N9Vzi']            = False     # (m/s); ; 
Morison['M4N1Vzi']            = False     # (m/s); ; 
Morison['M4N2Vzi']            = False     # (m/s); ; 
Morison['M4N3Vzi']            = False     # (m/s); ; 
Morison['M4N4Vzi']            = False     # (m/s); ; 
Morison['M4N5Vzi']            = False     # (m/s); ; 
Morison['M4N6Vzi']            = False     # (m/s); ; 
Morison['M4N7Vzi']            = False     # (m/s); ; 
Morison['M4N8Vzi']            = False     # (m/s); ; 
Morison['M4N9Vzi']            = False     # (m/s); ; 
Morison['M5N1Vzi']            = False     # (m/s); ; 
Morison['M5N2Vzi']            = False     # (m/s); ; 
Morison['M5N3Vzi']            = False     # (m/s); ; 
Morison['M5N4Vzi']            = False     # (m/s); ; 
Morison['M5N5Vzi']            = False     # (m/s); ; 
Morison['M5N6Vzi']            = False     # (m/s); ; 
Morison['M5N7Vzi']            = False     # (m/s); ; 
Morison['M5N8Vzi']            = False     # (m/s); ; 
Morison['M5N9Vzi']            = False     # (m/s); ; 
Morison['M6N1Vzi']            = False     # (m/s); ; 
Morison['M6N2Vzi']            = False     # (m/s); ; 
Morison['M6N3Vzi']            = False     # (m/s); ; 
Morison['M6N4Vzi']            = False     # (m/s); ; 
Morison['M6N5Vzi']            = False     # (m/s); ; 
Morison['M6N6Vzi']            = False     # (m/s); ; 
Morison['M6N7Vzi']            = False     # (m/s); ; 
Morison['M6N8Vzi']            = False     # (m/s); ; 
Morison['M6N9Vzi']            = False     # (m/s); ; 
Morison['M7N1Vzi']            = False     # (m/s); ; 
Morison['M7N2Vzi']            = False     # (m/s); ; 
Morison['M7N3Vzi']            = False     # (m/s); ; 
Morison['M7N4Vzi']            = False     # (m/s); ; 
Morison['M7N5Vzi']            = False     # (m/s); ; 
Morison['M7N6Vzi']            = False     # (m/s); ; 
Morison['M7N7Vzi']            = False     # (m/s); ; 
Morison['M7N8Vzi']            = False     # (m/s); ; 
Morison['M7N9Vzi']            = False     # (m/s); ; 
Morison['M8N1Vzi']            = False     # (m/s); ; 
Morison['M8N2Vzi']            = False     # (m/s); ; 
Morison['M8N3Vzi']            = False     # (m/s); ; 
Morison['M8N4Vzi']            = False     # (m/s); ; 
Morison['M8N5Vzi']            = False     # (m/s); ; 
Morison['M8N6Vzi']            = False     # (m/s); ; 
Morison['M8N7Vzi']            = False     # (m/s); ; 
Morison['M8N8Vzi']            = False     # (m/s); ; 
Morison['M8N9Vzi']            = False     # (m/s); ; 
Morison['M9N1Vzi']            = False     # (m/s); ; 
Morison['M9N2Vzi']            = False     # (m/s); ; 
Morison['M9N3Vzi']            = False     # (m/s); ; 
Morison['M9N4Vzi']            = False     # (m/s); ; 
Morison['M9N5Vzi']            = False     # (m/s); ; 
Morison['M9N6Vzi']            = False     # (m/s); ; 
Morison['M9N7Vzi']            = False     # (m/s); ; 
Morison['M9N8Vzi']            = False     # (m/s); ; 
Morison['M9N9Vzi']            = False     # (m/s); ; 
Morison['M1N1DynP']           = False     # (Pa); fluid dynamic pressure; 
Morison['M1N2DynP']           = False     # (Pa); ; 
Morison['M1N3DynP']           = False     # (Pa); ; 
Morison['M1N4DynP']           = False     # (Pa); ; 
Morison['M1N5DynP']           = False     # (Pa); ; 
Morison['M1N6DynP']           = False     # (Pa); ; 
Morison['M1N7DynP']           = False     # (Pa); ; 
Morison['M1N8DynP']           = False     # (Pa); ; 
Morison['M1N9DynP']           = False     # (Pa); ; 
Morison['M2N1DynP']           = False     # (Pa); ; 
Morison['M2N2DynP']           = False     # (Pa); ; 
Morison['M2N3DynP']           = False     # (Pa); ; 
Morison['M2N4DynP']           = False     # (Pa); ; 
Morison['M2N5DynP']           = False     # (Pa); ; 
Morison['M2N6DynP']           = False     # (Pa); ; 
Morison['M2N7DynP']           = False     # (Pa); ; 
Morison['M2N8DynP']           = False     # (Pa); ; 
Morison['M2N9DynP']           = False     # (Pa); ; 
Morison['M3N1DynP']           = False     # (Pa); ; 
Morison['M3N2DynP']           = False     # (Pa); ; 
Morison['M3N3DynP']           = False     # (Pa); ; 
Morison['M3N4DynP']           = False     # (Pa); ; 
Morison['M3N5DynP']           = False     # (Pa); ; 
Morison['M3N6DynP']           = False     # (Pa); ; 
Morison['M3N7DynP']           = False     # (Pa); ; 
Morison['M3N8DynP']           = False     # (Pa); ; 
Morison['M3N9DynP']           = False     # (Pa); ; 
Morison['M4N1DynP']           = False     # (Pa); ; 
Morison['M4N2DynP']           = False     # (Pa); ; 
Morison['M4N3DynP']           = False     # (Pa); ; 
Morison['M4N4DynP']           = False     # (Pa); ; 
Morison['M4N5DynP']           = False     # (Pa); ; 
Morison['M4N6DynP']           = False     # (Pa); ; 
Morison['M4N7DynP']           = False     # (Pa); ; 
Morison['M4N8DynP']           = False     # (Pa); ; 
Morison['M4N9DynP']           = False     # (Pa); ; 
Morison['M5N1DynP']           = False     # (Pa); ; 
Morison['M5N2DynP']           = False     # (Pa); ; 
Morison['M5N3DynP']           = False     # (Pa); ; 
Morison['M5N4DynP']           = False     # (Pa); ; 
Morison['M5N5DynP']           = False     # (Pa); ; 
Morison['M5N6DynP']           = False     # (Pa); ; 
Morison['M5N7DynP']           = False     # (Pa); ; 
Morison['M5N8DynP']           = False     # (Pa); ; 
Morison['M5N9DynP']           = False     # (Pa); ; 
Morison['M6N1DynP']           = False     # (Pa); ; 
Morison['M6N2DynP']           = False     # (Pa); ; 
Morison['M6N3DynP']           = False     # (Pa); ; 
Morison['M6N4DynP']           = False     # (Pa); ; 
Morison['M6N5DynP']           = False     # (Pa); ; 
Morison['M6N6DynP']           = False     # (Pa); ; 
Morison['M6N7DynP']           = False     # (Pa); ; 
Morison['M6N8DynP']           = False     # (Pa); ; 
Morison['M6N9DynP']           = False     # (Pa); ; 
Morison['M7N1DynP']           = False     # (Pa); ; 
Morison['M7N2DynP']           = False     # (Pa); ; 
Morison['M7N3DynP']           = False     # (Pa); ; 
Morison['M7N4DynP']           = False     # (Pa); ; 
Morison['M7N5DynP']           = False     # (Pa); ; 
Morison['M7N6DynP']           = False     # (Pa); ; 
Morison['M7N7DynP']           = False     # (Pa); ; 
Morison['M7N8DynP']           = False     # (Pa); ; 
Morison['M7N9DynP']           = False     # (Pa); ; 
Morison['M8N1DynP']           = False     # (Pa); ; 
Morison['M8N2DynP']           = False     # (Pa); ; 
Morison['M8N3DynP']           = False     # (Pa); ; 
Morison['M8N4DynP']           = False     # (Pa); ; 
Morison['M8N5DynP']           = False     # (Pa); ; 
Morison['M8N6DynP']           = False     # (Pa); ; 
Morison['M8N7DynP']           = False     # (Pa); ; 
Morison['M8N8DynP']           = False     # (Pa); ; 
Morison['M8N9DynP']           = False     # (Pa); ; 
Morison['M9N1DynP']           = False     # (Pa); ; 
Morison['M9N2DynP']           = False     # (Pa); ; 
Morison['M9N3DynP']           = False     # (Pa); ; 
Morison['M9N4DynP']           = False     # (Pa); ; 
Morison['M9N5DynP']           = False     # (Pa); ; 
Morison['M9N6DynP']           = False     # (Pa); ; 
Morison['M9N7DynP']           = False     # (Pa); ; 
Morison['M9N8DynP']           = False     # (Pa); ; 
Morison['M9N9DynP']           = False     # (Pa); ; 
Morison['M1N1STVxi']          = False     # (m/s); structure translational velocity; 
Morison['M1N2STVxi']          = False     # (m/s); ; 
Morison['M1N3STVxi']          = False     # (m/s); ; 
Morison['M1N4STVxi']          = False     # (m/s); ; 
Morison['M1N5STVxi']          = False     # (m/s); ; 
Morison['M1N6STVxi']          = False     # (m/s); ; 
Morison['M1N7STVxi']          = False     # (m/s); ; 
Morison['M1N8STVxi']          = False     # (m/s); ; 
Morison['M1N9STVxi']          = False     # (m/s); ; 
Morison['M2N1STVxi']          = False     # (m/s); ; 
Morison['M2N2STVxi']          = False     # (m/s); ; 
Morison['M2N3STVxi']          = False     # (m/s); ; 
Morison['M2N4STVxi']          = False     # (m/s); ; 
Morison['M2N5STVxi']          = False     # (m/s); ; 
Morison['M2N6STVxi']          = False     # (m/s); ; 
Morison['M2N7STVxi']          = False     # (m/s); ; 
Morison['M2N8STVxi']          = False     # (m/s); ; 
Morison['M2N9STVxi']          = False     # (m/s); ; 
Morison['M3N1STVxi']          = False     # (m/s); ; 
Morison['M3N2STVxi']          = False     # (m/s); ; 
Morison['M3N3STVxi']          = False     # (m/s); ; 
Morison['M3N4STVxi']          = False     # (m/s); ; 
Morison['M3N5STVxi']          = False     # (m/s); ; 
Morison['M3N6STVxi']          = False     # (m/s); ; 
Morison['M3N7STVxi']          = False     # (m/s); ; 
Morison['M3N8STVxi']          = False     # (m/s); ; 
Morison['M3N9STVxi']          = False     # (m/s); ; 
Morison['M4N1STVxi']          = False     # (m/s); ; 
Morison['M4N2STVxi']          = False     # (m/s); ; 
Morison['M4N3STVxi']          = False     # (m/s); ; 
Morison['M4N4STVxi']          = False     # (m/s); ; 
Morison['M4N5STVxi']          = False     # (m/s); ; 
Morison['M4N6STVxi']          = False     # (m/s); ; 
Morison['M4N7STVxi']          = False     # (m/s); ; 
Morison['M4N8STVxi']          = False     # (m/s); ; 
Morison['M4N9STVxi']          = False     # (m/s); ; 
Morison['M5N1STVxi']          = False     # (m/s); ; 
Morison['M5N2STVxi']          = False     # (m/s); ; 
Morison['M5N3STVxi']          = False     # (m/s); ; 
Morison['M5N4STVxi']          = False     # (m/s); ; 
Morison['M5N5STVxi']          = False     # (m/s); ; 
Morison['M5N6STVxi']          = False     # (m/s); ; 
Morison['M5N7STVxi']          = False     # (m/s); ; 
Morison['M5N8STVxi']          = False     # (m/s); ; 
Morison['M5N9STVxi']          = False     # (m/s); ; 
Morison['M6N1STVxi']          = False     # (m/s); ; 
Morison['M6N2STVxi']          = False     # (m/s); ; 
Morison['M6N3STVxi']          = False     # (m/s); ; 
Morison['M6N4STVxi']          = False     # (m/s); ; 
Morison['M6N5STVxi']          = False     # (m/s); ; 
Morison['M6N6STVxi']          = False     # (m/s); ; 
Morison['M6N7STVxi']          = False     # (m/s); ; 
Morison['M6N8STVxi']          = False     # (m/s); ; 
Morison['M6N9STVxi']          = False     # (m/s); ; 
Morison['M7N1STVxi']          = False     # (m/s); ; 
Morison['M7N2STVxi']          = False     # (m/s); ; 
Morison['M7N3STVxi']          = False     # (m/s); ; 
Morison['M7N4STVxi']          = False     # (m/s); ; 
Morison['M7N5STVxi']          = False     # (m/s); ; 
Morison['M7N6STVxi']          = False     # (m/s); ; 
Morison['M7N7STVxi']          = False     # (m/s); ; 
Morison['M7N8STVxi']          = False     # (m/s); ; 
Morison['M7N9STVxi']          = False     # (m/s); ; 
Morison['M8N1STVxi']          = False     # (m/s); ; 
Morison['M8N2STVxi']          = False     # (m/s); ; 
Morison['M8N3STVxi']          = False     # (m/s); ; 
Morison['M8N4STVxi']          = False     # (m/s); ; 
Morison['M8N5STVxi']          = False     # (m/s); ; 
Morison['M8N6STVxi']          = False     # (m/s); ; 
Morison['M8N7STVxi']          = False     # (m/s); ; 
Morison['M8N8STVxi']          = False     # (m/s); ; 
Morison['M8N9STVxi']          = False     # (m/s); ; 
Morison['M9N1STVxi']          = False     # (m/s); ; 
Morison['M9N2STVxi']          = False     # (m/s); ; 
Morison['M9N3STVxi']          = False     # (m/s); ; 
Morison['M9N4STVxi']          = False     # (m/s); ; 
Morison['M9N5STVxi']          = False     # (m/s); ; 
Morison['M9N6STVxi']          = False     # (m/s); ; 
Morison['M9N7STVxi']          = False     # (m/s); ; 
Morison['M9N8STVxi']          = False     # (m/s); ; 
Morison['M9N9STVxi']          = False     # (m/s); ; 
Morison['M1N1STVyi']          = False     # (m/s); ; 
Morison['M1N2STVyi']          = False     # (m/s); ; 
Morison['M1N3STVyi']          = False     # (m/s); ; 
Morison['M1N4STVyi']          = False     # (m/s); ; 
Morison['M1N5STVyi']          = False     # (m/s); ; 
Morison['M1N6STVyi']          = False     # (m/s); ; 
Morison['M1N7STVyi']          = False     # (m/s); ; 
Morison['M1N8STVyi']          = False     # (m/s); ; 
Morison['M1N9STVyi']          = False     # (m/s); ; 
Morison['M2N1STVyi']          = False     # (m/s); ; 
Morison['M2N2STVyi']          = False     # (m/s); ; 
Morison['M2N3STVyi']          = False     # (m/s); ; 
Morison['M2N4STVyi']          = False     # (m/s); ; 
Morison['M2N5STVyi']          = False     # (m/s); ; 
Morison['M2N6STVyi']          = False     # (m/s); ; 
Morison['M2N7STVyi']          = False     # (m/s); ; 
Morison['M2N8STVyi']          = False     # (m/s); ; 
Morison['M2N9STVyi']          = False     # (m/s); ; 
Morison['M3N1STVyi']          = False     # (m/s); ; 
Morison['M3N2STVyi']          = False     # (m/s); ; 
Morison['M3N3STVyi']          = False     # (m/s); ; 
Morison['M3N4STVyi']          = False     # (m/s); ; 
Morison['M3N5STVyi']          = False     # (m/s); ; 
Morison['M3N6STVyi']          = False     # (m/s); ; 
Morison['M3N7STVyi']          = False     # (m/s); ; 
Morison['M3N8STVyi']          = False     # (m/s); ; 
Morison['M3N9STVyi']          = False     # (m/s); ; 
Morison['M4N1STVyi']          = False     # (m/s); ; 
Morison['M4N2STVyi']          = False     # (m/s); ; 
Morison['M4N3STVyi']          = False     # (m/s); ; 
Morison['M4N4STVyi']          = False     # (m/s); ; 
Morison['M4N5STVyi']          = False     # (m/s); ; 
Morison['M4N6STVyi']          = False     # (m/s); ; 
Morison['M4N7STVyi']          = False     # (m/s); ; 
Morison['M4N8STVyi']          = False     # (m/s); ; 
Morison['M4N9STVyi']          = False     # (m/s); ; 
Morison['M5N1STVyi']          = False     # (m/s); ; 
Morison['M5N2STVyi']          = False     # (m/s); ; 
Morison['M5N3STVyi']          = False     # (m/s); ; 
Morison['M5N4STVyi']          = False     # (m/s); ; 
Morison['M5N5STVyi']          = False     # (m/s); ; 
Morison['M5N6STVyi']          = False     # (m/s); ; 
Morison['M5N7STVyi']          = False     # (m/s); ; 
Morison['M5N8STVyi']          = False     # (m/s); ; 
Morison['M5N9STVyi']          = False     # (m/s); ; 
Morison['M6N1STVyi']          = False     # (m/s); ; 
Morison['M6N2STVyi']          = False     # (m/s); ; 
Morison['M6N3STVyi']          = False     # (m/s); ; 
Morison['M6N4STVyi']          = False     # (m/s); ; 
Morison['M6N5STVyi']          = False     # (m/s); ; 
Morison['M6N6STVyi']          = False     # (m/s); ; 
Morison['M6N7STVyi']          = False     # (m/s); ; 
Morison['M6N8STVyi']          = False     # (m/s); ; 
Morison['M6N9STVyi']          = False     # (m/s); ; 
Morison['M7N1STVyi']          = False     # (m/s); ; 
Morison['M7N2STVyi']          = False     # (m/s); ; 
Morison['M7N3STVyi']          = False     # (m/s); ; 
Morison['M7N4STVyi']          = False     # (m/s); ; 
Morison['M7N5STVyi']          = False     # (m/s); ; 
Morison['M7N6STVyi']          = False     # (m/s); ; 
Morison['M7N7STVyi']          = False     # (m/s); ; 
Morison['M7N8STVyi']          = False     # (m/s); ; 
Morison['M7N9STVyi']          = False     # (m/s); ; 
Morison['M8N1STVyi']          = False     # (m/s); ; 
Morison['M8N2STVyi']          = False     # (m/s); ; 
Morison['M8N3STVyi']          = False     # (m/s); ; 
Morison['M8N4STVyi']          = False     # (m/s); ; 
Morison['M8N5STVyi']          = False     # (m/s); ; 
Morison['M8N6STVyi']          = False     # (m/s); ; 
Morison['M8N7STVyi']          = False     # (m/s); ; 
Morison['M8N8STVyi']          = False     # (m/s); ; 
Morison['M8N9STVyi']          = False     # (m/s); ; 
Morison['M9N1STVyi']          = False     # (m/s); ; 
Morison['M9N2STVyi']          = False     # (m/s); ; 
Morison['M9N3STVyi']          = False     # (m/s); ; 
Morison['M9N4STVyi']          = False     # (m/s); ; 
Morison['M9N5STVyi']          = False     # (m/s); ; 
Morison['M9N6STVyi']          = False     # (m/s); ; 
Morison['M9N7STVyi']          = False     # (m/s); ; 
Morison['M9N8STVyi']          = False     # (m/s); ; 
Morison['M9N9STVyi']          = False     # (m/s); ; 
Morison['M1N1STVzi']          = False     # (m/s); ; 
Morison['M1N2STVzi']          = False     # (m/s); ; 
Morison['M1N3STVzi']          = False     # (m/s); ; 
Morison['M1N4STVzi']          = False     # (m/s); ; 
Morison['M1N5STVzi']          = False     # (m/s); ; 
Morison['M1N6STVzi']          = False     # (m/s); ; 
Morison['M1N7STVzi']          = False     # (m/s); ; 
Morison['M1N8STVzi']          = False     # (m/s); ; 
Morison['M1N9STVzi']          = False     # (m/s); ; 
Morison['M2N1STVzi']          = False     # (m/s); ; 
Morison['M2N2STVzi']          = False     # (m/s); ; 
Morison['M2N3STVzi']          = False     # (m/s); ; 
Morison['M2N4STVzi']          = False     # (m/s); ; 
Morison['M2N5STVzi']          = False     # (m/s); ; 
Morison['M2N6STVzi']          = False     # (m/s); ; 
Morison['M2N7STVzi']          = False     # (m/s); ; 
Morison['M2N8STVzi']          = False     # (m/s); ; 
Morison['M2N9STVzi']          = False     # (m/s); ; 
Morison['M3N1STVzi']          = False     # (m/s); ; 
Morison['M3N2STVzi']          = False     # (m/s); ; 
Morison['M3N3STVzi']          = False     # (m/s); ; 
Morison['M3N4STVzi']          = False     # (m/s); ; 
Morison['M3N5STVzi']          = False     # (m/s); ; 
Morison['M3N6STVzi']          = False     # (m/s); ; 
Morison['M3N7STVzi']          = False     # (m/s); ; 
Morison['M3N8STVzi']          = False     # (m/s); ; 
Morison['M3N9STVzi']          = False     # (m/s); ; 
Morison['M4N1STVzi']          = False     # (m/s); ; 
Morison['M4N2STVzi']          = False     # (m/s); ; 
Morison['M4N3STVzi']          = False     # (m/s); ; 
Morison['M4N4STVzi']          = False     # (m/s); ; 
Morison['M4N5STVzi']          = False     # (m/s); ; 
Morison['M4N6STVzi']          = False     # (m/s); ; 
Morison['M4N7STVzi']          = False     # (m/s); ; 
Morison['M4N8STVzi']          = False     # (m/s); ; 
Morison['M4N9STVzi']          = False     # (m/s); ; 
Morison['M5N1STVzi']          = False     # (m/s); ; 
Morison['M5N2STVzi']          = False     # (m/s); ; 
Morison['M5N3STVzi']          = False     # (m/s); ; 
Morison['M5N4STVzi']          = False     # (m/s); ; 
Morison['M5N5STVzi']          = False     # (m/s); ; 
Morison['M5N6STVzi']          = False     # (m/s); ; 
Morison['M5N7STVzi']          = False     # (m/s); ; 
Morison['M5N8STVzi']          = False     # (m/s); ; 
Morison['M5N9STVzi']          = False     # (m/s); ; 
Morison['M6N1STVzi']          = False     # (m/s); ; 
Morison['M6N2STVzi']          = False     # (m/s); ; 
Morison['M6N3STVzi']          = False     # (m/s); ; 
Morison['M6N4STVzi']          = False     # (m/s); ; 
Morison['M6N5STVzi']          = False     # (m/s); ; 
Morison['M6N6STVzi']          = False     # (m/s); ; 
Morison['M6N7STVzi']          = False     # (m/s); ; 
Morison['M6N8STVzi']          = False     # (m/s); ; 
Morison['M6N9STVzi']          = False     # (m/s); ; 
Morison['M7N1STVzi']          = False     # (m/s); ; 
Morison['M7N2STVzi']          = False     # (m/s); ; 
Morison['M7N3STVzi']          = False     # (m/s); ; 
Morison['M7N4STVzi']          = False     # (m/s); ; 
Morison['M7N5STVzi']          = False     # (m/s); ; 
Morison['M7N6STVzi']          = False     # (m/s); ; 
Morison['M7N7STVzi']          = False     # (m/s); ; 
Morison['M7N8STVzi']          = False     # (m/s); ; 
Morison['M7N9STVzi']          = False     # (m/s); ; 
Morison['M8N1STVzi']          = False     # (m/s); ; 
Morison['M8N2STVzi']          = False     # (m/s); ; 
Morison['M8N3STVzi']          = False     # (m/s); ; 
Morison['M8N4STVzi']          = False     # (m/s); ; 
Morison['M8N5STVzi']          = False     # (m/s); ; 
Morison['M8N6STVzi']          = False     # (m/s); ; 
Morison['M8N7STVzi']          = False     # (m/s); ; 
Morison['M8N8STVzi']          = False     # (m/s); ; 
Morison['M8N9STVzi']          = False     # (m/s); ; 
Morison['M9N1STVzi']          = False     # (m/s); ; 
Morison['M9N2STVzi']          = False     # (m/s); ; 
Morison['M9N3STVzi']          = False     # (m/s); ; 
Morison['M9N4STVzi']          = False     # (m/s); ; 
Morison['M9N5STVzi']          = False     # (m/s); ; 
Morison['M9N6STVzi']          = False     # (m/s); ; 
Morison['M9N7STVzi']          = False     # (m/s); ; 
Morison['M9N8STVzi']          = False     # (m/s); ; 
Morison['M9N9STVzi']          = False     # (m/s); ; 
Morison['M1N1STAxi']          = False     # (m/s^2); structure translational Acceleration; 
Morison['M1N2STAxi']          = False     # (m/s^2); ; 
Morison['M1N3STAxi']          = False     # (m/s^2); ; 
Morison['M1N4STAxi']          = False     # (m/s^2); ; 
Morison['M1N5STAxi']          = False     # (m/s^2); ; 
Morison['M1N6STAxi']          = False     # (m/s^2); ; 
Morison['M1N7STAxi']          = False     # (m/s^2); ; 
Morison['M1N8STAxi']          = False     # (m/s^2); ; 
Morison['M1N9STAxi']          = False     # (m/s^2); ; 
Morison['M2N1STAxi']          = False     # (m/s^2); ; 
Morison['M2N2STAxi']          = False     # (m/s^2); ; 
Morison['M2N3STAxi']          = False     # (m/s^2); ; 
Morison['M2N4STAxi']          = False     # (m/s^2); ; 
Morison['M2N5STAxi']          = False     # (m/s^2); ; 
Morison['M2N6STAxi']          = False     # (m/s^2); ; 
Morison['M2N7STAxi']          = False     # (m/s^2); ; 
Morison['M2N8STAxi']          = False     # (m/s^2); ; 
Morison['M2N9STAxi']          = False     # (m/s^2); ; 
Morison['M3N1STAxi']          = False     # (m/s^2); ; 
Morison['M3N2STAxi']          = False     # (m/s^2); ; 
Morison['M3N3STAxi']          = False     # (m/s^2); ; 
Morison['M3N4STAxi']          = False     # (m/s^2); ; 
Morison['M3N5STAxi']          = False     # (m/s^2); ; 
Morison['M3N6STAxi']          = False     # (m/s^2); ; 
Morison['M3N7STAxi']          = False     # (m/s^2); ; 
Morison['M3N8STAxi']          = False     # (m/s^2); ; 
Morison['M3N9STAxi']          = False     # (m/s^2); ; 
Morison['M4N1STAxi']          = False     # (m/s^2); ; 
Morison['M4N2STAxi']          = False     # (m/s^2); ; 
Morison['M4N3STAxi']          = False     # (m/s^2); ; 
Morison['M4N4STAxi']          = False     # (m/s^2); ; 
Morison['M4N5STAxi']          = False     # (m/s^2); ; 
Morison['M4N6STAxi']          = False     # (m/s^2); ; 
Morison['M4N7STAxi']          = False     # (m/s^2); ; 
Morison['M4N8STAxi']          = False     # (m/s^2); ; 
Morison['M4N9STAxi']          = False     # (m/s^2); ; 
Morison['M5N1STAxi']          = False     # (m/s^2); ; 
Morison['M5N2STAxi']          = False     # (m/s^2); ; 
Morison['M5N3STAxi']          = False     # (m/s^2); ; 
Morison['M5N4STAxi']          = False     # (m/s^2); ; 
Morison['M5N5STAxi']          = False     # (m/s^2); ; 
Morison['M5N6STAxi']          = False     # (m/s^2); ; 
Morison['M5N7STAxi']          = False     # (m/s^2); ; 
Morison['M5N8STAxi']          = False     # (m/s^2); ; 
Morison['M5N9STAxi']          = False     # (m/s^2); ; 
Morison['M6N1STAxi']          = False     # (m/s^2); ; 
Morison['M6N2STAxi']          = False     # (m/s^2); ; 
Morison['M6N3STAxi']          = False     # (m/s^2); ; 
Morison['M6N4STAxi']          = False     # (m/s^2); ; 
Morison['M6N5STAxi']          = False     # (m/s^2); ; 
Morison['M6N6STAxi']          = False     # (m/s^2); ; 
Morison['M6N7STAxi']          = False     # (m/s^2); ; 
Morison['M6N8STAxi']          = False     # (m/s^2); ; 
Morison['M6N9STAxi']          = False     # (m/s^2); ; 
Morison['M7N1STAxi']          = False     # (m/s^2); ; 
Morison['M7N2STAxi']          = False     # (m/s^2); ; 
Morison['M7N3STAxi']          = False     # (m/s^2); ; 
Morison['M7N4STAxi']          = False     # (m/s^2); ; 
Morison['M7N5STAxi']          = False     # (m/s^2); ; 
Morison['M7N6STAxi']          = False     # (m/s^2); ; 
Morison['M7N7STAxi']          = False     # (m/s^2); ; 
Morison['M7N8STAxi']          = False     # (m/s^2); ; 
Morison['M7N9STAxi']          = False     # (m/s^2); ; 
Morison['M8N1STAxi']          = False     # (m/s^2); ; 
Morison['M8N2STAxi']          = False     # (m/s^2); ; 
Morison['M8N3STAxi']          = False     # (m/s^2); ; 
Morison['M8N4STAxi']          = False     # (m/s^2); ; 
Morison['M8N5STAxi']          = False     # (m/s^2); ; 
Morison['M8N6STAxi']          = False     # (m/s^2); ; 
Morison['M8N7STAxi']          = False     # (m/s^2); ; 
Morison['M8N8STAxi']          = False     # (m/s^2); ; 
Morison['M8N9STAxi']          = False     # (m/s^2); ; 
Morison['M9N1STAxi']          = False     # (m/s^2); ; 
Morison['M9N2STAxi']          = False     # (m/s^2); ; 
Morison['M9N3STAxi']          = False     # (m/s^2); ; 
Morison['M9N4STAxi']          = False     # (m/s^2); ; 
Morison['M9N5STAxi']          = False     # (m/s^2); ; 
Morison['M9N6STAxi']          = False     # (m/s^2); ; 
Morison['M9N7STAxi']          = False     # (m/s^2); ; 
Morison['M9N8STAxi']          = False     # (m/s^2); ; 
Morison['M9N9STAxi']          = False     # (m/s^2); ; 
Morison['M1N1STAyi']          = False     # (m/s^2); ; 
Morison['M1N2STAyi']          = False     # (m/s^2); ; 
Morison['M1N3STAyi']          = False     # (m/s^2); ; 
Morison['M1N4STAyi']          = False     # (m/s^2); ; 
Morison['M1N5STAyi']          = False     # (m/s^2); ; 
Morison['M1N6STAyi']          = False     # (m/s^2); ; 
Morison['M1N7STAyi']          = False     # (m/s^2); ; 
Morison['M1N8STAyi']          = False     # (m/s^2); ; 
Morison['M1N9STAyi']          = False     # (m/s^2); ; 
Morison['M2N1STAyi']          = False     # (m/s^2); ; 
Morison['M2N2STAyi']          = False     # (m/s^2); ; 
Morison['M2N3STAyi']          = False     # (m/s^2); ; 
Morison['M2N4STAyi']          = False     # (m/s^2); ; 
Morison['M2N5STAyi']          = False     # (m/s^2); ; 
Morison['M2N6STAyi']          = False     # (m/s^2); ; 
Morison['M2N7STAyi']          = False     # (m/s^2); ; 
Morison['M2N8STAyi']          = False     # (m/s^2); ; 
Morison['M2N9STAyi']          = False     # (m/s^2); ; 
Morison['M3N1STAyi']          = False     # (m/s^2); ; 
Morison['M3N2STAyi']          = False     # (m/s^2); ; 
Morison['M3N3STAyi']          = False     # (m/s^2); ; 
Morison['M3N4STAyi']          = False     # (m/s^2); ; 
Morison['M3N5STAyi']          = False     # (m/s^2); ; 
Morison['M3N6STAyi']          = False     # (m/s^2); ; 
Morison['M3N7STAyi']          = False     # (m/s^2); ; 
Morison['M3N8STAyi']          = False     # (m/s^2); ; 
Morison['M3N9STAyi']          = False     # (m/s^2); ; 
Morison['M4N1STAyi']          = False     # (m/s^2); ; 
Morison['M4N2STAyi']          = False     # (m/s^2); ; 
Morison['M4N3STAyi']          = False     # (m/s^2); ; 
Morison['M4N4STAyi']          = False     # (m/s^2); ; 
Morison['M4N5STAyi']          = False     # (m/s^2); ; 
Morison['M4N6STAyi']          = False     # (m/s^2); ; 
Morison['M4N7STAyi']          = False     # (m/s^2); ; 
Morison['M4N8STAyi']          = False     # (m/s^2); ; 
Morison['M4N9STAyi']          = False     # (m/s^2); ; 
Morison['M5N1STAyi']          = False     # (m/s^2); ; 
Morison['M5N2STAyi']          = False     # (m/s^2); ; 
Morison['M5N3STAyi']          = False     # (m/s^2); ; 
Morison['M5N4STAyi']          = False     # (m/s^2); ; 
Morison['M5N5STAyi']          = False     # (m/s^2); ; 
Morison['M5N6STAyi']          = False     # (m/s^2); ; 
Morison['M5N7STAyi']          = False     # (m/s^2); ; 
Morison['M5N8STAyi']          = False     # (m/s^2); ; 
Morison['M5N9STAyi']          = False     # (m/s^2); ; 
Morison['M6N1STAyi']          = False     # (m/s^2); ; 
Morison['M6N2STAyi']          = False     # (m/s^2); ; 
Morison['M6N3STAyi']          = False     # (m/s^2); ; 
Morison['M6N4STAyi']          = False     # (m/s^2); ; 
Morison['M6N5STAyi']          = False     # (m/s^2); ; 
Morison['M6N6STAyi']          = False     # (m/s^2); ; 
Morison['M6N7STAyi']          = False     # (m/s^2); ; 
Morison['M6N8STAyi']          = False     # (m/s^2); ; 
Morison['M6N9STAyi']          = False     # (m/s^2); ; 
Morison['M7N1STAyi']          = False     # (m/s^2); ; 
Morison['M7N2STAyi']          = False     # (m/s^2); ; 
Morison['M7N3STAyi']          = False     # (m/s^2); ; 
Morison['M7N4STAyi']          = False     # (m/s^2); ; 
Morison['M7N5STAyi']          = False     # (m/s^2); ; 
Morison['M7N6STAyi']          = False     # (m/s^2); ; 
Morison['M7N7STAyi']          = False     # (m/s^2); ; 
Morison['M7N8STAyi']          = False     # (m/s^2); ; 
Morison['M7N9STAyi']          = False     # (m/s^2); ; 
Morison['M8N1STAyi']          = False     # (m/s^2); ; 
Morison['M8N2STAyi']          = False     # (m/s^2); ; 
Morison['M8N3STAyi']          = False     # (m/s^2); ; 
Morison['M8N4STAyi']          = False     # (m/s^2); ; 
Morison['M8N5STAyi']          = False     # (m/s^2); ; 
Morison['M8N6STAyi']          = False     # (m/s^2); ; 
Morison['M8N7STAyi']          = False     # (m/s^2); ; 
Morison['M8N8STAyi']          = False     # (m/s^2); ; 
Morison['M8N9STAyi']          = False     # (m/s^2); ; 
Morison['M9N1STAyi']          = False     # (m/s^2); ; 
Morison['M9N2STAyi']          = False     # (m/s^2); ; 
Morison['M9N3STAyi']          = False     # (m/s^2); ; 
Morison['M9N4STAyi']          = False     # (m/s^2); ; 
Morison['M9N5STAyi']          = False     # (m/s^2); ; 
Morison['M9N6STAyi']          = False     # (m/s^2); ; 
Morison['M9N7STAyi']          = False     # (m/s^2); ; 
Morison['M9N8STAyi']          = False     # (m/s^2); ; 
Morison['M9N9STAyi']          = False     # (m/s^2); ; 
Morison['M1N1STAzi']          = False     # (m/s^2); ; 
Morison['M1N2STAzi']          = False     # (m/s^2); ; 
Morison['M1N3STAzi']          = False     # (m/s^2); ; 
Morison['M1N4STAzi']          = False     # (m/s^2); ; 
Morison['M1N5STAzi']          = False     # (m/s^2); ; 
Morison['M1N6STAzi']          = False     # (m/s^2); ; 
Morison['M1N7STAzi']          = False     # (m/s^2); ; 
Morison['M1N8STAzi']          = False     # (m/s^2); ; 
Morison['M1N9STAzi']          = False     # (m/s^2); ; 
Morison['M2N1STAzi']          = False     # (m/s^2); ; 
Morison['M2N2STAzi']          = False     # (m/s^2); ; 
Morison['M2N3STAzi']          = False     # (m/s^2); ; 
Morison['M2N4STAzi']          = False     # (m/s^2); ; 
Morison['M2N5STAzi']          = False     # (m/s^2); ; 
Morison['M2N6STAzi']          = False     # (m/s^2); ; 
Morison['M2N7STAzi']          = False     # (m/s^2); ; 
Morison['M2N8STAzi']          = False     # (m/s^2); ; 
Morison['M2N9STAzi']          = False     # (m/s^2); ; 
Morison['M3N1STAzi']          = False     # (m/s^2); ; 
Morison['M3N2STAzi']          = False     # (m/s^2); ; 
Morison['M3N3STAzi']          = False     # (m/s^2); ; 
Morison['M3N4STAzi']          = False     # (m/s^2); ; 
Morison['M3N5STAzi']          = False     # (m/s^2); ; 
Morison['M3N6STAzi']          = False     # (m/s^2); ; 
Morison['M3N7STAzi']          = False     # (m/s^2); ; 
Morison['M3N8STAzi']          = False     # (m/s^2); ; 
Morison['M3N9STAzi']          = False     # (m/s^2); ; 
Morison['M4N1STAzi']          = False     # (m/s^2); ; 
Morison['M4N2STAzi']          = False     # (m/s^2); ; 
Morison['M4N3STAzi']          = False     # (m/s^2); ; 
Morison['M4N4STAzi']          = False     # (m/s^2); ; 
Morison['M4N5STAzi']          = False     # (m/s^2); ; 
Morison['M4N6STAzi']          = False     # (m/s^2); ; 
Morison['M4N7STAzi']          = False     # (m/s^2); ; 
Morison['M4N8STAzi']          = False     # (m/s^2); ; 
Morison['M4N9STAzi']          = False     # (m/s^2); ; 
Morison['M5N1STAzi']          = False     # (m/s^2); ; 
Morison['M5N2STAzi']          = False     # (m/s^2); ; 
Morison['M5N3STAzi']          = False     # (m/s^2); ; 
Morison['M5N4STAzi']          = False     # (m/s^2); ; 
Morison['M5N5STAzi']          = False     # (m/s^2); ; 
Morison['M5N6STAzi']          = False     # (m/s^2); ; 
Morison['M5N7STAzi']          = False     # (m/s^2); ; 
Morison['M5N8STAzi']          = False     # (m/s^2); ; 
Morison['M5N9STAzi']          = False     # (m/s^2); ; 
Morison['M6N1STAzi']          = False     # (m/s^2); ; 
Morison['M6N2STAzi']          = False     # (m/s^2); ; 
Morison['M6N3STAzi']          = False     # (m/s^2); ; 
Morison['M6N4STAzi']          = False     # (m/s^2); ; 
Morison['M6N5STAzi']          = False     # (m/s^2); ; 
Morison['M6N6STAzi']          = False     # (m/s^2); ; 
Morison['M6N7STAzi']          = False     # (m/s^2); ; 
Morison['M6N8STAzi']          = False     # (m/s^2); ; 
Morison['M6N9STAzi']          = False     # (m/s^2); ; 
Morison['M7N1STAzi']          = False     # (m/s^2); ; 
Morison['M7N2STAzi']          = False     # (m/s^2); ; 
Morison['M7N3STAzi']          = False     # (m/s^2); ; 
Morison['M7N4STAzi']          = False     # (m/s^2); ; 
Morison['M7N5STAzi']          = False     # (m/s^2); ; 
Morison['M7N6STAzi']          = False     # (m/s^2); ; 
Morison['M7N7STAzi']          = False     # (m/s^2); ; 
Morison['M7N8STAzi']          = False     # (m/s^2); ; 
Morison['M7N9STAzi']          = False     # (m/s^2); ; 
Morison['M8N1STAzi']          = False     # (m/s^2); ; 
Morison['M8N2STAzi']          = False     # (m/s^2); ; 
Morison['M8N3STAzi']          = False     # (m/s^2); ; 
Morison['M8N4STAzi']          = False     # (m/s^2); ; 
Morison['M8N5STAzi']          = False     # (m/s^2); ; 
Morison['M8N6STAzi']          = False     # (m/s^2); ; 
Morison['M8N7STAzi']          = False     # (m/s^2); ; 
Morison['M8N8STAzi']          = False     # (m/s^2); ; 
Morison['M8N9STAzi']          = False     # (m/s^2); ; 
Morison['M9N1STAzi']          = False     # (m/s^2); ; 
Morison['M9N2STAzi']          = False     # (m/s^2); ; 
Morison['M9N3STAzi']          = False     # (m/s^2); ; 
Morison['M9N4STAzi']          = False     # (m/s^2); ; 
Morison['M9N5STAzi']          = False     # (m/s^2); ; 
Morison['M9N6STAzi']          = False     # (m/s^2); ; 
Morison['M9N7STAzi']          = False     # (m/s^2); ; 
Morison['M9N8STAzi']          = False     # (m/s^2); ; 
Morison['M9N9STAzi']          = False     # (m/s^2); ; 

# Morison Element Loads
Morison['M1N1FDxi']           = False     # (N/m); x-component of the distributed viscous-drag force expressed in the inertial coordinate system; 
Morison['M1N2FDxi']           = False     # (N/m); ; 
Morison['M1N3FDxi']           = False     # (N/m); ; 
Morison['M1N4FDxi']           = False     # (N/m); ; 
Morison['M1N5FDxi']           = False     # (N/m); ; 
Morison['M1N6FDxi']           = False     # (N/m); ; 
Morison['M1N7FDxi']           = False     # (N/m); ; 
Morison['M1N8FDxi']           = False     # (N/m); ; 
Morison['M1N9FDxi']           = False     # (N/m); ; 
Morison['M2N1FDxi']           = False     # (N/m); ; 
Morison['M2N2FDxi']           = False     # (N/m); ; 
Morison['M2N3FDxi']           = False     # (N/m); ; 
Morison['M2N4FDxi']           = False     # (N/m); ; 
Morison['M2N5FDxi']           = False     # (N/m); ; 
Morison['M2N6FDxi']           = False     # (N/m); ; 
Morison['M2N7FDxi']           = False     # (N/m); ; 
Morison['M2N8FDxi']           = False     # (N/m); ; 
Morison['M2N9FDxi']           = False     # (N/m); ; 
Morison['M3N1FDxi']           = False     # (N/m); ; 
Morison['M3N2FDxi']           = False     # (N/m); ; 
Morison['M3N3FDxi']           = False     # (N/m); ; 
Morison['M3N4FDxi']           = False     # (N/m); ; 
Morison['M3N5FDxi']           = False     # (N/m); ; 
Morison['M3N6FDxi']           = False     # (N/m); ; 
Morison['M3N7FDxi']           = False     # (N/m); ; 
Morison['M3N8FDxi']           = False     # (N/m); ; 
Morison['M3N9FDxi']           = False     # (N/m); ; 
Morison['M4N1FDxi']           = False     # (N/m); ; 
Morison['M4N2FDxi']           = False     # (N/m); ; 
Morison['M4N3FDxi']           = False     # (N/m); ; 
Morison['M4N4FDxi']           = False     # (N/m); ; 
Morison['M4N5FDxi']           = False     # (N/m); ; 
Morison['M4N6FDxi']           = False     # (N/m); ; 
Morison['M4N7FDxi']           = False     # (N/m); ; 
Morison['M4N8FDxi']           = False     # (N/m); ; 
Morison['M4N9FDxi']           = False     # (N/m); ; 
Morison['M5N1FDxi']           = False     # (N/m); ; 
Morison['M5N2FDxi']           = False     # (N/m); ; 
Morison['M5N3FDxi']           = False     # (N/m); ; 
Morison['M5N4FDxi']           = False     # (N/m); ; 
Morison['M5N5FDxi']           = False     # (N/m); ; 
Morison['M5N6FDxi']           = False     # (N/m); ; 
Morison['M5N7FDxi']           = False     # (N/m); ; 
Morison['M5N8FDxi']           = False     # (N/m); ; 
Morison['M5N9FDxi']           = False     # (N/m); ; 
Morison['M6N1FDxi']           = False     # (N/m); ; 
Morison['M6N2FDxi']           = False     # (N/m); ; 
Morison['M6N3FDxi']           = False     # (N/m); ; 
Morison['M6N4FDxi']           = False     # (N/m); ; 
Morison['M6N5FDxi']           = False     # (N/m); ; 
Morison['M6N6FDxi']           = False     # (N/m); ; 
Morison['M6N7FDxi']           = False     # (N/m); ; 
Morison['M6N8FDxi']           = False     # (N/m); ; 
Morison['M6N9FDxi']           = False     # (N/m); ; 
Morison['M7N1FDxi']           = False     # (N/m); ; 
Morison['M7N2FDxi']           = False     # (N/m); ; 
Morison['M7N3FDxi']           = False     # (N/m); ; 
Morison['M7N4FDxi']           = False     # (N/m); ; 
Morison['M7N5FDxi']           = False     # (N/m); ; 
Morison['M7N6FDxi']           = False     # (N/m); ; 
Morison['M7N7FDxi']           = False     # (N/m); ; 
Morison['M7N8FDxi']           = False     # (N/m); ; 
Morison['M7N9FDxi']           = False     # (N/m); ; 
Morison['M8N1FDxi']           = False     # (N/m); ; 
Morison['M8N2FDxi']           = False     # (N/m); ; 
Morison['M8N3FDxi']           = False     # (N/m); ; 
Morison['M8N4FDxi']           = False     # (N/m); ; 
Morison['M8N5FDxi']           = False     # (N/m); ; 
Morison['M8N6FDxi']           = False     # (N/m); ; 
Morison['M8N7FDxi']           = False     # (N/m); ; 
Morison['M8N8FDxi']           = False     # (N/m); ; 
Morison['M8N9FDxi']           = False     # (N/m); ; 
Morison['M9N1FDxi']           = False     # (N/m); ; 
Morison['M9N2FDxi']           = False     # (N/m); ; 
Morison['M9N3FDxi']           = False     # (N/m); ; 
Morison['M9N4FDxi']           = False     # (N/m); ; 
Morison['M9N5FDxi']           = False     # (N/m); ; 
Morison['M9N6FDxi']           = False     # (N/m); ; 
Morison['M9N7FDxi']           = False     # (N/m); ; 
Morison['M9N8FDxi']           = False     # (N/m); ; 
Morison['M9N9FDxi']           = False     # (N/m); ; 
Morison['M1N1FDyi']           = False     # (N/m); y-component of the distributed viscous-drag force expressed in the inertial coordinate system; 
Morison['M1N2FDyi']           = False     # (N/m); ; 
Morison['M1N3FDyi']           = False     # (N/m); ; 
Morison['M1N4FDyi']           = False     # (N/m); ; 
Morison['M1N5FDyi']           = False     # (N/m); ; 
Morison['M1N6FDyi']           = False     # (N/m); ; 
Morison['M1N7FDyi']           = False     # (N/m); ; 
Morison['M1N8FDyi']           = False     # (N/m); ; 
Morison['M1N9FDyi']           = False     # (N/m); ; 
Morison['M2N1FDyi']           = False     # (N/m); ; 
Morison['M2N2FDyi']           = False     # (N/m); ; 
Morison['M2N3FDyi']           = False     # (N/m); ; 
Morison['M2N4FDyi']           = False     # (N/m); ; 
Morison['M2N5FDyi']           = False     # (N/m); ; 
Morison['M2N6FDyi']           = False     # (N/m); ; 
Morison['M2N7FDyi']           = False     # (N/m); ; 
Morison['M2N8FDyi']           = False     # (N/m); ; 
Morison['M2N9FDyi']           = False     # (N/m); ; 
Morison['M3N1FDyi']           = False     # (N/m); ; 
Morison['M3N2FDyi']           = False     # (N/m); ; 
Morison['M3N3FDyi']           = False     # (N/m); ; 
Morison['M3N4FDyi']           = False     # (N/m); ; 
Morison['M3N5FDyi']           = False     # (N/m); ; 
Morison['M3N6FDyi']           = False     # (N/m); ; 
Morison['M3N7FDyi']           = False     # (N/m); ; 
Morison['M3N8FDyi']           = False     # (N/m); ; 
Morison['M3N9FDyi']           = False     # (N/m); ; 
Morison['M4N1FDyi']           = False     # (N/m); ; 
Morison['M4N2FDyi']           = False     # (N/m); ; 
Morison['M4N3FDyi']           = False     # (N/m); ; 
Morison['M4N4FDyi']           = False     # (N/m); ; 
Morison['M4N5FDyi']           = False     # (N/m); ; 
Morison['M4N6FDyi']           = False     # (N/m); ; 
Morison['M4N7FDyi']           = False     # (N/m); ; 
Morison['M4N8FDyi']           = False     # (N/m); ; 
Morison['M4N9FDyi']           = False     # (N/m); ; 
Morison['M5N1FDyi']           = False     # (N/m); ; 
Morison['M5N2FDyi']           = False     # (N/m); ; 
Morison['M5N3FDyi']           = False     # (N/m); ; 
Morison['M5N4FDyi']           = False     # (N/m); ; 
Morison['M5N5FDyi']           = False     # (N/m); ; 
Morison['M5N6FDyi']           = False     # (N/m); ; 
Morison['M5N7FDyi']           = False     # (N/m); ; 
Morison['M5N8FDyi']           = False     # (N/m); ; 
Morison['M5N9FDyi']           = False     # (N/m); ; 
Morison['M6N1FDyi']           = False     # (N/m); ; 
Morison['M6N2FDyi']           = False     # (N/m); ; 
Morison['M6N3FDyi']           = False     # (N/m); ; 
Morison['M6N4FDyi']           = False     # (N/m); ; 
Morison['M6N5FDyi']           = False     # (N/m); ; 
Morison['M6N6FDyi']           = False     # (N/m); ; 
Morison['M6N7FDyi']           = False     # (N/m); ; 
Morison['M6N8FDyi']           = False     # (N/m); ; 
Morison['M6N9FDyi']           = False     # (N/m); ; 
Morison['M7N1FDyi']           = False     # (N/m); ; 
Morison['M7N2FDyi']           = False     # (N/m); ; 
Morison['M7N3FDyi']           = False     # (N/m); ; 
Morison['M7N4FDyi']           = False     # (N/m); ; 
Morison['M7N5FDyi']           = False     # (N/m); ; 
Morison['M7N6FDyi']           = False     # (N/m); ; 
Morison['M7N7FDyi']           = False     # (N/m); ; 
Morison['M7N8FDyi']           = False     # (N/m); ; 
Morison['M7N9FDyi']           = False     # (N/m); ; 
Morison['M8N1FDyi']           = False     # (N/m); ; 
Morison['M8N2FDyi']           = False     # (N/m); ; 
Morison['M8N3FDyi']           = False     # (N/m); ; 
Morison['M8N4FDyi']           = False     # (N/m); ; 
Morison['M8N5FDyi']           = False     # (N/m); ; 
Morison['M8N6FDyi']           = False     # (N/m); ; 
Morison['M8N7FDyi']           = False     # (N/m); ; 
Morison['M8N8FDyi']           = False     # (N/m); ; 
Morison['M8N9FDyi']           = False     # (N/m); ; 
Morison['M9N1FDyi']           = False     # (N/m); ; 
Morison['M9N2FDyi']           = False     # (N/m); ; 
Morison['M9N3FDyi']           = False     # (N/m); ; 
Morison['M9N4FDyi']           = False     # (N/m); ; 
Morison['M9N5FDyi']           = False     # (N/m); ; 
Morison['M9N6FDyi']           = False     # (N/m); ; 
Morison['M9N7FDyi']           = False     # (N/m); ; 
Morison['M9N8FDyi']           = False     # (N/m); ; 
Morison['M9N9FDyi']           = False     # (N/m); ; 
Morison['M1N1FDzi']           = False     # (N/m); z-component of the distributed viscous-drag force expressed in the inertial coordinate system; 
Morison['M1N2FDzi']           = False     # (N/m); ; 
Morison['M1N3FDzi']           = False     # (N/m); ; 
Morison['M1N4FDzi']           = False     # (N/m); ; 
Morison['M1N5FDzi']           = False     # (N/m); ; 
Morison['M1N6FDzi']           = False     # (N/m); ; 
Morison['M1N7FDzi']           = False     # (N/m); ; 
Morison['M1N8FDzi']           = False     # (N/m); ; 
Morison['M1N9FDzi']           = False     # (N/m); ; 
Morison['M2N1FDzi']           = False     # (N/m); ; 
Morison['M2N2FDzi']           = False     # (N/m); ; 
Morison['M2N3FDzi']           = False     # (N/m); ; 
Morison['M2N4FDzi']           = False     # (N/m); ; 
Morison['M2N5FDzi']           = False     # (N/m); ; 
Morison['M2N6FDzi']           = False     # (N/m); ; 
Morison['M2N7FDzi']           = False     # (N/m); ; 
Morison['M2N8FDzi']           = False     # (N/m); ; 
Morison['M2N9FDzi']           = False     # (N/m); ; 
Morison['M3N1FDzi']           = False     # (N/m); ; 
Morison['M3N2FDzi']           = False     # (N/m); ; 
Morison['M3N3FDzi']           = False     # (N/m); ; 
Morison['M3N4FDzi']           = False     # (N/m); ; 
Morison['M3N5FDzi']           = False     # (N/m); ; 
Morison['M3N6FDzi']           = False     # (N/m); ; 
Morison['M3N7FDzi']           = False     # (N/m); ; 
Morison['M3N8FDzi']           = False     # (N/m); ; 
Morison['M3N9FDzi']           = False     # (N/m); ; 
Morison['M4N1FDzi']           = False     # (N/m); ; 
Morison['M4N2FDzi']           = False     # (N/m); ; 
Morison['M4N3FDzi']           = False     # (N/m); ; 
Morison['M4N4FDzi']           = False     # (N/m); ; 
Morison['M4N5FDzi']           = False     # (N/m); ; 
Morison['M4N6FDzi']           = False     # (N/m); ; 
Morison['M4N7FDzi']           = False     # (N/m); ; 
Morison['M4N8FDzi']           = False     # (N/m); ; 
Morison['M4N9FDzi']           = False     # (N/m); ; 
Morison['M5N1FDzi']           = False     # (N/m); ; 
Morison['M5N2FDzi']           = False     # (N/m); ; 
Morison['M5N3FDzi']           = False     # (N/m); ; 
Morison['M5N4FDzi']           = False     # (N/m); ; 
Morison['M5N5FDzi']           = False     # (N/m); ; 
Morison['M5N6FDzi']           = False     # (N/m); ; 
Morison['M5N7FDzi']           = False     # (N/m); ; 
Morison['M5N8FDzi']           = False     # (N/m); ; 
Morison['M5N9FDzi']           = False     # (N/m); ; 
Morison['M6N1FDzi']           = False     # (N/m); ; 
Morison['M6N2FDzi']           = False     # (N/m); ; 
Morison['M6N3FDzi']           = False     # (N/m); ; 
Morison['M6N4FDzi']           = False     # (N/m); ; 
Morison['M6N5FDzi']           = False     # (N/m); ; 
Morison['M6N6FDzi']           = False     # (N/m); ; 
Morison['M6N7FDzi']           = False     # (N/m); ; 
Morison['M6N8FDzi']           = False     # (N/m); ; 
Morison['M6N9FDzi']           = False     # (N/m); ; 
Morison['M7N1FDzi']           = False     # (N/m); ; 
Morison['M7N2FDzi']           = False     # (N/m); ; 
Morison['M7N3FDzi']           = False     # (N/m); ; 
Morison['M7N4FDzi']           = False     # (N/m); ; 
Morison['M7N5FDzi']           = False     # (N/m); ; 
Morison['M7N6FDzi']           = False     # (N/m); ; 
Morison['M7N7FDzi']           = False     # (N/m); ; 
Morison['M7N8FDzi']           = False     # (N/m); ; 
Morison['M7N9FDzi']           = False     # (N/m); ; 
Morison['M8N1FDzi']           = False     # (N/m); ; 
Morison['M8N2FDzi']           = False     # (N/m); ; 
Morison['M8N3FDzi']           = False     # (N/m); ; 
Morison['M8N4FDzi']           = False     # (N/m); ; 
Morison['M8N5FDzi']           = False     # (N/m); ; 
Morison['M8N6FDzi']           = False     # (N/m); ; 
Morison['M8N7FDzi']           = False     # (N/m); ; 
Morison['M8N8FDzi']           = False     # (N/m); ; 
Morison['M8N9FDzi']           = False     # (N/m); ; 
Morison['M9N1FDzi']           = False     # (N/m); ; 
Morison['M9N2FDzi']           = False     # (N/m); ; 
Morison['M9N3FDzi']           = False     # (N/m); ; 
Morison['M9N4FDzi']           = False     # (N/m); ; 
Morison['M9N5FDzi']           = False     # (N/m); ; 
Morison['M9N6FDzi']           = False     # (N/m); ; 
Morison['M9N7FDzi']           = False     # (N/m); ; 
Morison['M9N8FDzi']           = False     # (N/m); ; 
Morison['M9N9FDzi']           = False     # (N/m); ; 
Morison['M1N1FIxi']           = False     # (N/m); x-component of the distributed fluid inertia force expressed in the inertial coordinate system; 
Morison['M1N2FIxi']           = False     # (N/m); ; 
Morison['M1N3FIxi']           = False     # (N/m); ; 
Morison['M1N4FIxi']           = False     # (N/m); ; 
Morison['M1N5FIxi']           = False     # (N/m); ; 
Morison['M1N6FIxi']           = False     # (N/m); ; 
Morison['M1N7FIxi']           = False     # (N/m); ; 
Morison['M1N8FIxi']           = False     # (N/m); ; 
Morison['M1N9FIxi']           = False     # (N/m); ; 
Morison['M2N1FIxi']           = False     # (N/m); ; 
Morison['M2N2FIxi']           = False     # (N/m); ; 
Morison['M2N3FIxi']           = False     # (N/m); ; 
Morison['M2N4FIxi']           = False     # (N/m); ; 
Morison['M2N5FIxi']           = False     # (N/m); ; 
Morison['M2N6FIxi']           = False     # (N/m); ; 
Morison['M2N7FIxi']           = False     # (N/m); ; 
Morison['M2N8FIxi']           = False     # (N/m); ; 
Morison['M2N9FIxi']           = False     # (N/m); ; 
Morison['M3N1FIxi']           = False     # (N/m); ; 
Morison['M3N2FIxi']           = False     # (N/m); ; 
Morison['M3N3FIxi']           = False     # (N/m); ; 
Morison['M3N4FIxi']           = False     # (N/m); ; 
Morison['M3N5FIxi']           = False     # (N/m); ; 
Morison['M3N6FIxi']           = False     # (N/m); ; 
Morison['M3N7FIxi']           = False     # (N/m); ; 
Morison['M3N8FIxi']           = False     # (N/m); ; 
Morison['M3N9FIxi']           = False     # (N/m); ; 
Morison['M4N1FIxi']           = False     # (N/m); ; 
Morison['M4N2FIxi']           = False     # (N/m); ; 
Morison['M4N3FIxi']           = False     # (N/m); ; 
Morison['M4N4FIxi']           = False     # (N/m); ; 
Morison['M4N5FIxi']           = False     # (N/m); ; 
Morison['M4N6FIxi']           = False     # (N/m); ; 
Morison['M4N7FIxi']           = False     # (N/m); ; 
Morison['M4N8FIxi']           = False     # (N/m); ; 
Morison['M4N9FIxi']           = False     # (N/m); ; 
Morison['M5N1FIxi']           = False     # (N/m); ; 
Morison['M5N2FIxi']           = False     # (N/m); ; 
Morison['M5N3FIxi']           = False     # (N/m); ; 
Morison['M5N4FIxi']           = False     # (N/m); ; 
Morison['M5N5FIxi']           = False     # (N/m); ; 
Morison['M5N6FIxi']           = False     # (N/m); ; 
Morison['M5N7FIxi']           = False     # (N/m); ; 
Morison['M5N8FIxi']           = False     # (N/m); ; 
Morison['M5N9FIxi']           = False     # (N/m); ; 
Morison['M6N1FIxi']           = False     # (N/m); ; 
Morison['M6N2FIxi']           = False     # (N/m); ; 
Morison['M6N3FIxi']           = False     # (N/m); ; 
Morison['M6N4FIxi']           = False     # (N/m); ; 
Morison['M6N5FIxi']           = False     # (N/m); ; 
Morison['M6N6FIxi']           = False     # (N/m); ; 
Morison['M6N7FIxi']           = False     # (N/m); ; 
Morison['M6N8FIxi']           = False     # (N/m); ; 
Morison['M6N9FIxi']           = False     # (N/m); ; 
Morison['M7N1FIxi']           = False     # (N/m); ; 
Morison['M7N2FIxi']           = False     # (N/m); ; 
Morison['M7N3FIxi']           = False     # (N/m); ; 
Morison['M7N4FIxi']           = False     # (N/m); ; 
Morison['M7N5FIxi']           = False     # (N/m); ; 
Morison['M7N6FIxi']           = False     # (N/m); ; 
Morison['M7N7FIxi']           = False     # (N/m); ; 
Morison['M7N8FIxi']           = False     # (N/m); ; 
Morison['M7N9FIxi']           = False     # (N/m); ; 
Morison['M8N1FIxi']           = False     # (N/m); ; 
Morison['M8N2FIxi']           = False     # (N/m); ; 
Morison['M8N3FIxi']           = False     # (N/m); ; 
Morison['M8N4FIxi']           = False     # (N/m); ; 
Morison['M8N5FIxi']           = False     # (N/m); ; 
Morison['M8N6FIxi']           = False     # (N/m); ; 
Morison['M8N7FIxi']           = False     # (N/m); ; 
Morison['M8N8FIxi']           = False     # (N/m); ; 
Morison['M8N9FIxi']           = False     # (N/m); ; 
Morison['M9N1FIxi']           = False     # (N/m); ; 
Morison['M9N2FIxi']           = False     # (N/m); ; 
Morison['M9N3FIxi']           = False     # (N/m); ; 
Morison['M9N4FIxi']           = False     # (N/m); ; 
Morison['M9N5FIxi']           = False     # (N/m); ; 
Morison['M9N6FIxi']           = False     # (N/m); ; 
Morison['M9N7FIxi']           = False     # (N/m); ; 
Morison['M9N8FIxi']           = False     # (N/m); ; 
Morison['M9N9FIxi']           = False     # (N/m); ; 
Morison['M1N1FIyi']           = False     # (N/m); y-component of the distributed fluid inertia force expressed in the inertial coordinate system; 
Morison['M1N2FIyi']           = False     # (N/m); ; 
Morison['M1N3FIyi']           = False     # (N/m); ; 
Morison['M1N4FIyi']           = False     # (N/m); ; 
Morison['M1N5FIyi']           = False     # (N/m); ; 
Morison['M1N6FIyi']           = False     # (N/m); ; 
Morison['M1N7FIyi']           = False     # (N/m); ; 
Morison['M1N8FIyi']           = False     # (N/m); ; 
Morison['M1N9FIyi']           = False     # (N/m); ; 
Morison['M2N1FIyi']           = False     # (N/m); ; 
Morison['M2N2FIyi']           = False     # (N/m); ; 
Morison['M2N3FIyi']           = False     # (N/m); ; 
Morison['M2N4FIyi']           = False     # (N/m); ; 
Morison['M2N5FIyi']           = False     # (N/m); ; 
Morison['M2N6FIyi']           = False     # (N/m); ; 
Morison['M2N7FIyi']           = False     # (N/m); ; 
Morison['M2N8FIyi']           = False     # (N/m); ; 
Morison['M2N9FIyi']           = False     # (N/m); ; 
Morison['M3N1FIyi']           = False     # (N/m); ; 
Morison['M3N2FIyi']           = False     # (N/m); ; 
Morison['M3N3FIyi']           = False     # (N/m); ; 
Morison['M3N4FIyi']           = False     # (N/m); ; 
Morison['M3N5FIyi']           = False     # (N/m); ; 
Morison['M3N6FIyi']           = False     # (N/m); ; 
Morison['M3N7FIyi']           = False     # (N/m); ; 
Morison['M3N8FIyi']           = False     # (N/m); ; 
Morison['M3N9FIyi']           = False     # (N/m); ; 
Morison['M4N1FIyi']           = False     # (N/m); ; 
Morison['M4N2FIyi']           = False     # (N/m); ; 
Morison['M4N3FIyi']           = False     # (N/m); ; 
Morison['M4N4FIyi']           = False     # (N/m); ; 
Morison['M4N5FIyi']           = False     # (N/m); ; 
Morison['M4N6FIyi']           = False     # (N/m); ; 
Morison['M4N7FIyi']           = False     # (N/m); ; 
Morison['M4N8FIyi']           = False     # (N/m); ; 
Morison['M4N9FIyi']           = False     # (N/m); ; 
Morison['M5N1FIyi']           = False     # (N/m); ; 
Morison['M5N2FIyi']           = False     # (N/m); ; 
Morison['M5N3FIyi']           = False     # (N/m); ; 
Morison['M5N4FIyi']           = False     # (N/m); ; 
Morison['M5N5FIyi']           = False     # (N/m); ; 
Morison['M5N6FIyi']           = False     # (N/m); ; 
Morison['M5N7FIyi']           = False     # (N/m); ; 
Morison['M5N8FIyi']           = False     # (N/m); ; 
Morison['M5N9FIyi']           = False     # (N/m); ; 
Morison['M6N1FIyi']           = False     # (N/m); ; 
Morison['M6N2FIyi']           = False     # (N/m); ; 
Morison['M6N3FIyi']           = False     # (N/m); ; 
Morison['M6N4FIyi']           = False     # (N/m); ; 
Morison['M6N5FIyi']           = False     # (N/m); ; 
Morison['M6N6FIyi']           = False     # (N/m); ; 
Morison['M6N7FIyi']           = False     # (N/m); ; 
Morison['M6N8FIyi']           = False     # (N/m); ; 
Morison['M6N9FIyi']           = False     # (N/m); ; 
Morison['M7N1FIyi']           = False     # (N/m); ; 
Morison['M7N2FIyi']           = False     # (N/m); ; 
Morison['M7N3FIyi']           = False     # (N/m); ; 
Morison['M7N4FIyi']           = False     # (N/m); ; 
Morison['M7N5FIyi']           = False     # (N/m); ; 
Morison['M7N6FIyi']           = False     # (N/m); ; 
Morison['M7N7FIyi']           = False     # (N/m); ; 
Morison['M7N8FIyi']           = False     # (N/m); ; 
Morison['M7N9FIyi']           = False     # (N/m); ; 
Morison['M8N1FIyi']           = False     # (N/m); ; 
Morison['M8N2FIyi']           = False     # (N/m); ; 
Morison['M8N3FIyi']           = False     # (N/m); ; 
Morison['M8N4FIyi']           = False     # (N/m); ; 
Morison['M8N5FIyi']           = False     # (N/m); ; 
Morison['M8N6FIyi']           = False     # (N/m); ; 
Morison['M8N7FIyi']           = False     # (N/m); ; 
Morison['M8N8FIyi']           = False     # (N/m); ; 
Morison['M8N9FIyi']           = False     # (N/m); ; 
Morison['M9N1FIyi']           = False     # (N/m); ; 
Morison['M9N2FIyi']           = False     # (N/m); ; 
Morison['M9N3FIyi']           = False     # (N/m); ; 
Morison['M9N4FIyi']           = False     # (N/m); ; 
Morison['M9N5FIyi']           = False     # (N/m); ; 
Morison['M9N6FIyi']           = False     # (N/m); ; 
Morison['M9N7FIyi']           = False     # (N/m); ; 
Morison['M9N8FIyi']           = False     # (N/m); ; 
Morison['M9N9FIyi']           = False     # (N/m); ; 
Morison['M1N1FIzi']           = False     # (N/m); z-component of the distributed fluid inertia force expressed in the inertial coordinate system; 
Morison['M1N2FIzi']           = False     # (N/m); ; 
Morison['M1N3FIzi']           = False     # (N/m); ; 
Morison['M1N4FIzi']           = False     # (N/m); ; 
Morison['M1N5FIzi']           = False     # (N/m); ; 
Morison['M1N6FIzi']           = False     # (N/m); ; 
Morison['M1N7FIzi']           = False     # (N/m); ; 
Morison['M1N8FIzi']           = False     # (N/m); ; 
Morison['M1N9FIzi']           = False     # (N/m); ; 
Morison['M2N1FIzi']           = False     # (N/m); ; 
Morison['M2N2FIzi']           = False     # (N/m); ; 
Morison['M2N3FIzi']           = False     # (N/m); ; 
Morison['M2N4FIzi']           = False     # (N/m); ; 
Morison['M2N5FIzi']           = False     # (N/m); ; 
Morison['M2N6FIzi']           = False     # (N/m); ; 
Morison['M2N7FIzi']           = False     # (N/m); ; 
Morison['M2N8FIzi']           = False     # (N/m); ; 
Morison['M2N9FIzi']           = False     # (N/m); ; 
Morison['M3N1FIzi']           = False     # (N/m); ; 
Morison['M3N2FIzi']           = False     # (N/m); ; 
Morison['M3N3FIzi']           = False     # (N/m); ; 
Morison['M3N4FIzi']           = False     # (N/m); ; 
Morison['M3N5FIzi']           = False     # (N/m); ; 
Morison['M3N6FIzi']           = False     # (N/m); ; 
Morison['M3N7FIzi']           = False     # (N/m); ; 
Morison['M3N8FIzi']           = False     # (N/m); ; 
Morison['M3N9FIzi']           = False     # (N/m); ; 
Morison['M4N1FIzi']           = False     # (N/m); ; 
Morison['M4N2FIzi']           = False     # (N/m); ; 
Morison['M4N3FIzi']           = False     # (N/m); ; 
Morison['M4N4FIzi']           = False     # (N/m); ; 
Morison['M4N5FIzi']           = False     # (N/m); ; 
Morison['M4N6FIzi']           = False     # (N/m); ; 
Morison['M4N7FIzi']           = False     # (N/m); ; 
Morison['M4N8FIzi']           = False     # (N/m); ; 
Morison['M4N9FIzi']           = False     # (N/m); ; 
Morison['M5N1FIzi']           = False     # (N/m); ; 
Morison['M5N2FIzi']           = False     # (N/m); ; 
Morison['M5N3FIzi']           = False     # (N/m); ; 
Morison['M5N4FIzi']           = False     # (N/m); ; 
Morison['M5N5FIzi']           = False     # (N/m); ; 
Morison['M5N6FIzi']           = False     # (N/m); ; 
Morison['M5N7FIzi']           = False     # (N/m); ; 
Morison['M5N8FIzi']           = False     # (N/m); ; 
Morison['M5N9FIzi']           = False     # (N/m); ; 
Morison['M6N1FIzi']           = False     # (N/m); ; 
Morison['M6N2FIzi']           = False     # (N/m); ; 
Morison['M6N3FIzi']           = False     # (N/m); ; 
Morison['M6N4FIzi']           = False     # (N/m); ; 
Morison['M6N5FIzi']           = False     # (N/m); ; 
Morison['M6N6FIzi']           = False     # (N/m); ; 
Morison['M6N7FIzi']           = False     # (N/m); ; 
Morison['M6N8FIzi']           = False     # (N/m); ; 
Morison['M6N9FIzi']           = False     # (N/m); ; 
Morison['M7N1FIzi']           = False     # (N/m); ; 
Morison['M7N2FIzi']           = False     # (N/m); ; 
Morison['M7N3FIzi']           = False     # (N/m); ; 
Morison['M7N4FIzi']           = False     # (N/m); ; 
Morison['M7N5FIzi']           = False     # (N/m); ; 
Morison['M7N6FIzi']           = False     # (N/m); ; 
Morison['M7N7FIzi']           = False     # (N/m); ; 
Morison['M7N8FIzi']           = False     # (N/m); ; 
Morison['M7N9FIzi']           = False     # (N/m); ; 
Morison['M8N1FIzi']           = False     # (N/m); ; 
Morison['M8N2FIzi']           = False     # (N/m); ; 
Morison['M8N3FIzi']           = False     # (N/m); ; 
Morison['M8N4FIzi']           = False     # (N/m); ; 
Morison['M8N5FIzi']           = False     # (N/m); ; 
Morison['M8N6FIzi']           = False     # (N/m); ; 
Morison['M8N7FIzi']           = False     # (N/m); ; 
Morison['M8N8FIzi']           = False     # (N/m); ; 
Morison['M8N9FIzi']           = False     # (N/m); ; 
Morison['M9N1FIzi']           = False     # (N/m); ; 
Morison['M9N2FIzi']           = False     # (N/m); ; 
Morison['M9N3FIzi']           = False     # (N/m); ; 
Morison['M9N4FIzi']           = False     # (N/m); ; 
Morison['M9N5FIzi']           = False     # (N/m); ; 
Morison['M9N6FIzi']           = False     # (N/m); ; 
Morison['M9N7FIzi']           = False     # (N/m); ; 
Morison['M9N8FIzi']           = False     # (N/m); ; 
Morison['M9N9FIzi']           = False     # (N/m); ; 
Morison['M1N1FBxi']           = False     # (N/m); x-component of the distributed bouyancy force expressed in the inertial coordinate system; 
Morison['M1N2FBxi']           = False     # (N/m); ; 
Morison['M1N3FBxi']           = False     # (N/m); ; 
Morison['M1N4FBxi']           = False     # (N/m); ; 
Morison['M1N5FBxi']           = False     # (N/m); ; 
Morison['M1N6FBxi']           = False     # (N/m); ; 
Morison['M1N7FBxi']           = False     # (N/m); ; 
Morison['M1N8FBxi']           = False     # (N/m); ; 
Morison['M1N9FBxi']           = False     # (N/m); ; 
Morison['M2N1FBxi']           = False     # (N/m); ; 
Morison['M2N2FBxi']           = False     # (N/m); ; 
Morison['M2N3FBxi']           = False     # (N/m); ; 
Morison['M2N4FBxi']           = False     # (N/m); ; 
Morison['M2N5FBxi']           = False     # (N/m); ; 
Morison['M2N6FBxi']           = False     # (N/m); ; 
Morison['M2N7FBxi']           = False     # (N/m); ; 
Morison['M2N8FBxi']           = False     # (N/m); ; 
Morison['M2N9FBxi']           = False     # (N/m); ; 
Morison['M3N1FBxi']           = False     # (N/m); ; 
Morison['M3N2FBxi']           = False     # (N/m); ; 
Morison['M3N3FBxi']           = False     # (N/m); ; 
Morison['M3N4FBxi']           = False     # (N/m); ; 
Morison['M3N5FBxi']           = False     # (N/m); ; 
Morison['M3N6FBxi']           = False     # (N/m); ; 
Morison['M3N7FBxi']           = False     # (N/m); ; 
Morison['M3N8FBxi']           = False     # (N/m); ; 
Morison['M3N9FBxi']           = False     # (N/m); ; 
Morison['M4N1FBxi']           = False     # (N/m); ; 
Morison['M4N2FBxi']           = False     # (N/m); ; 
Morison['M4N3FBxi']           = False     # (N/m); ; 
Morison['M4N4FBxi']           = False     # (N/m); ; 
Morison['M4N5FBxi']           = False     # (N/m); ; 
Morison['M4N6FBxi']           = False     # (N/m); ; 
Morison['M4N7FBxi']           = False     # (N/m); ; 
Morison['M4N8FBxi']           = False     # (N/m); ; 
Morison['M4N9FBxi']           = False     # (N/m); ; 
Morison['M5N1FBxi']           = False     # (N/m); ; 
Morison['M5N2FBxi']           = False     # (N/m); ; 
Morison['M5N3FBxi']           = False     # (N/m); ; 
Morison['M5N4FBxi']           = False     # (N/m); ; 
Morison['M5N5FBxi']           = False     # (N/m); ; 
Morison['M5N6FBxi']           = False     # (N/m); ; 
Morison['M5N7FBxi']           = False     # (N/m); ; 
Morison['M5N8FBxi']           = False     # (N/m); ; 
Morison['M5N9FBxi']           = False     # (N/m); ; 
Morison['M6N1FBxi']           = False     # (N/m); ; 
Morison['M6N2FBxi']           = False     # (N/m); ; 
Morison['M6N3FBxi']           = False     # (N/m); ; 
Morison['M6N4FBxi']           = False     # (N/m); ; 
Morison['M6N5FBxi']           = False     # (N/m); ; 
Morison['M6N6FBxi']           = False     # (N/m); ; 
Morison['M6N7FBxi']           = False     # (N/m); ; 
Morison['M6N8FBxi']           = False     # (N/m); ; 
Morison['M6N9FBxi']           = False     # (N/m); ; 
Morison['M7N1FBxi']           = False     # (N/m); ; 
Morison['M7N2FBxi']           = False     # (N/m); ; 
Morison['M7N3FBxi']           = False     # (N/m); ; 
Morison['M7N4FBxi']           = False     # (N/m); ; 
Morison['M7N5FBxi']           = False     # (N/m); ; 
Morison['M7N6FBxi']           = False     # (N/m); ; 
Morison['M7N7FBxi']           = False     # (N/m); ; 
Morison['M7N8FBxi']           = False     # (N/m); ; 
Morison['M7N9FBxi']           = False     # (N/m); ; 
Morison['M8N1FBxi']           = False     # (N/m); ; 
Morison['M8N2FBxi']           = False     # (N/m); ; 
Morison['M8N3FBxi']           = False     # (N/m); ; 
Morison['M8N4FBxi']           = False     # (N/m); ; 
Morison['M8N5FBxi']           = False     # (N/m); ; 
Morison['M8N6FBxi']           = False     # (N/m); ; 
Morison['M8N7FBxi']           = False     # (N/m); ; 
Morison['M8N8FBxi']           = False     # (N/m); ; 
Morison['M8N9FBxi']           = False     # (N/m); ; 
Morison['M9N1FBxi']           = False     # (N/m); ; 
Morison['M9N2FBxi']           = False     # (N/m); ; 
Morison['M9N3FBxi']           = False     # (N/m); ; 
Morison['M9N4FBxi']           = False     # (N/m); ; 
Morison['M9N5FBxi']           = False     # (N/m); ; 
Morison['M9N6FBxi']           = False     # (N/m); ; 
Morison['M9N7FBxi']           = False     # (N/m); ; 
Morison['M9N8FBxi']           = False     # (N/m); ; 
Morison['M9N9FBxi']           = False     # (N/m); ; 
Morison['M1N1FByi']           = False     # (N/m); y-component of the distributed bouyancy force expressed in the inertial coordinate system; 
Morison['M1N2FByi']           = False     # (N/m); ; 
Morison['M1N3FByi']           = False     # (N/m); ; 
Morison['M1N4FByi']           = False     # (N/m); ; 
Morison['M1N5FByi']           = False     # (N/m); ; 
Morison['M1N6FByi']           = False     # (N/m); ; 
Morison['M1N7FByi']           = False     # (N/m); ; 
Morison['M1N8FByi']           = False     # (N/m); ; 
Morison['M1N9FByi']           = False     # (N/m); ; 
Morison['M2N1FByi']           = False     # (N/m); ; 
Morison['M2N2FByi']           = False     # (N/m); ; 
Morison['M2N3FByi']           = False     # (N/m); ; 
Morison['M2N4FByi']           = False     # (N/m); ; 
Morison['M2N5FByi']           = False     # (N/m); ; 
Morison['M2N6FByi']           = False     # (N/m); ; 
Morison['M2N7FByi']           = False     # (N/m); ; 
Morison['M2N8FByi']           = False     # (N/m); ; 
Morison['M2N9FByi']           = False     # (N/m); ; 
Morison['M3N1FByi']           = False     # (N/m); ; 
Morison['M3N2FByi']           = False     # (N/m); ; 
Morison['M3N3FByi']           = False     # (N/m); ; 
Morison['M3N4FByi']           = False     # (N/m); ; 
Morison['M3N5FByi']           = False     # (N/m); ; 
Morison['M3N6FByi']           = False     # (N/m); ; 
Morison['M3N7FByi']           = False     # (N/m); ; 
Morison['M3N8FByi']           = False     # (N/m); ; 
Morison['M3N9FByi']           = False     # (N/m); ; 
Morison['M4N1FByi']           = False     # (N/m); ; 
Morison['M4N2FByi']           = False     # (N/m); ; 
Morison['M4N3FByi']           = False     # (N/m); ; 
Morison['M4N4FByi']           = False     # (N/m); ; 
Morison['M4N5FByi']           = False     # (N/m); ; 
Morison['M4N6FByi']           = False     # (N/m); ; 
Morison['M4N7FByi']           = False     # (N/m); ; 
Morison['M4N8FByi']           = False     # (N/m); ; 
Morison['M4N9FByi']           = False     # (N/m); ; 
Morison['M5N1FByi']           = False     # (N/m); ; 
Morison['M5N2FByi']           = False     # (N/m); ; 
Morison['M5N3FByi']           = False     # (N/m); ; 
Morison['M5N4FByi']           = False     # (N/m); ; 
Morison['M5N5FByi']           = False     # (N/m); ; 
Morison['M5N6FByi']           = False     # (N/m); ; 
Morison['M5N7FByi']           = False     # (N/m); ; 
Morison['M5N8FByi']           = False     # (N/m); ; 
Morison['M5N9FByi']           = False     # (N/m); ; 
Morison['M6N1FByi']           = False     # (N/m); ; 
Morison['M6N2FByi']           = False     # (N/m); ; 
Morison['M6N3FByi']           = False     # (N/m); ; 
Morison['M6N4FByi']           = False     # (N/m); ; 
Morison['M6N5FByi']           = False     # (N/m); ; 
Morison['M6N6FByi']           = False     # (N/m); ; 
Morison['M6N7FByi']           = False     # (N/m); ; 
Morison['M6N8FByi']           = False     # (N/m); ; 
Morison['M6N9FByi']           = False     # (N/m); ; 
Morison['M7N1FByi']           = False     # (N/m); ; 
Morison['M7N2FByi']           = False     # (N/m); ; 
Morison['M7N3FByi']           = False     # (N/m); ; 
Morison['M7N4FByi']           = False     # (N/m); ; 
Morison['M7N5FByi']           = False     # (N/m); ; 
Morison['M7N6FByi']           = False     # (N/m); ; 
Morison['M7N7FByi']           = False     # (N/m); ; 
Morison['M7N8FByi']           = False     # (N/m); ; 
Morison['M7N9FByi']           = False     # (N/m); ; 
Morison['M8N1FByi']           = False     # (N/m); ; 
Morison['M8N2FByi']           = False     # (N/m); ; 
Morison['M8N3FByi']           = False     # (N/m); ; 
Morison['M8N4FByi']           = False     # (N/m); ; 
Morison['M8N5FByi']           = False     # (N/m); ; 
Morison['M8N6FByi']           = False     # (N/m); ; 
Morison['M8N7FByi']           = False     # (N/m); ; 
Morison['M8N8FByi']           = False     # (N/m); ; 
Morison['M8N9FByi']           = False     # (N/m); ; 
Morison['M9N1FByi']           = False     # (N/m); ; 
Morison['M9N2FByi']           = False     # (N/m); ; 
Morison['M9N3FByi']           = False     # (N/m); ; 
Morison['M9N4FByi']           = False     # (N/m); ; 
Morison['M9N5FByi']           = False     # (N/m); ; 
Morison['M9N6FByi']           = False     # (N/m); ; 
Morison['M9N7FByi']           = False     # (N/m); ; 
Morison['M9N8FByi']           = False     # (N/m); ; 
Morison['M9N9FByi']           = False     # (N/m); ; 
Morison['M1N1FBzi']           = False     # (N/m); z-component of the distributed bouyancy force expressed in the inertial coordinate system; 
Morison['M1N2FBzi']           = False     # (N/m); ; 
Morison['M1N3FBzi']           = False     # (N/m); ; 
Morison['M1N4FBzi']           = False     # (N/m); ; 
Morison['M1N5FBzi']           = False     # (N/m); ; 
Morison['M1N6FBzi']           = False     # (N/m); ; 
Morison['M1N7FBzi']           = False     # (N/m); ; 
Morison['M1N8FBzi']           = False     # (N/m); ; 
Morison['M1N9FBzi']           = False     # (N/m); ; 
Morison['M2N1FBzi']           = False     # (N/m); ; 
Morison['M2N2FBzi']           = False     # (N/m); ; 
Morison['M2N3FBzi']           = False     # (N/m); ; 
Morison['M2N4FBzi']           = False     # (N/m); ; 
Morison['M2N5FBzi']           = False     # (N/m); ; 
Morison['M2N6FBzi']           = False     # (N/m); ; 
Morison['M2N7FBzi']           = False     # (N/m); ; 
Morison['M2N8FBzi']           = False     # (N/m); ; 
Morison['M2N9FBzi']           = False     # (N/m); ; 
Morison['M3N1FBzi']           = False     # (N/m); ; 
Morison['M3N2FBzi']           = False     # (N/m); ; 
Morison['M3N3FBzi']           = False     # (N/m); ; 
Morison['M3N4FBzi']           = False     # (N/m); ; 
Morison['M3N5FBzi']           = False     # (N/m); ; 
Morison['M3N6FBzi']           = False     # (N/m); ; 
Morison['M3N7FBzi']           = False     # (N/m); ; 
Morison['M3N8FBzi']           = False     # (N/m); ; 
Morison['M3N9FBzi']           = False     # (N/m); ; 
Morison['M4N1FBzi']           = False     # (N/m); ; 
Morison['M4N2FBzi']           = False     # (N/m); ; 
Morison['M4N3FBzi']           = False     # (N/m); ; 
Morison['M4N4FBzi']           = False     # (N/m); ; 
Morison['M4N5FBzi']           = False     # (N/m); ; 
Morison['M4N6FBzi']           = False     # (N/m); ; 
Morison['M4N7FBzi']           = False     # (N/m); ; 
Morison['M4N8FBzi']           = False     # (N/m); ; 
Morison['M4N9FBzi']           = False     # (N/m); ; 
Morison['M5N1FBzi']           = False     # (N/m); ; 
Morison['M5N2FBzi']           = False     # (N/m); ; 
Morison['M5N3FBzi']           = False     # (N/m); ; 
Morison['M5N4FBzi']           = False     # (N/m); ; 
Morison['M5N5FBzi']           = False     # (N/m); ; 
Morison['M5N6FBzi']           = False     # (N/m); ; 
Morison['M5N7FBzi']           = False     # (N/m); ; 
Morison['M5N8FBzi']           = False     # (N/m); ; 
Morison['M5N9FBzi']           = False     # (N/m); ; 
Morison['M6N1FBzi']           = False     # (N/m); ; 
Morison['M6N2FBzi']           = False     # (N/m); ; 
Morison['M6N3FBzi']           = False     # (N/m); ; 
Morison['M6N4FBzi']           = False     # (N/m); ; 
Morison['M6N5FBzi']           = False     # (N/m); ; 
Morison['M6N6FBzi']           = False     # (N/m); ; 
Morison['M6N7FBzi']           = False     # (N/m); ; 
Morison['M6N8FBzi']           = False     # (N/m); ; 
Morison['M6N9FBzi']           = False     # (N/m); ; 
Morison['M7N1FBzi']           = False     # (N/m); ; 
Morison['M7N2FBzi']           = False     # (N/m); ; 
Morison['M7N3FBzi']           = False     # (N/m); ; 
Morison['M7N4FBzi']           = False     # (N/m); ; 
Morison['M7N5FBzi']           = False     # (N/m); ; 
Morison['M7N6FBzi']           = False     # (N/m); ; 
Morison['M7N7FBzi']           = False     # (N/m); ; 
Morison['M7N8FBzi']           = False     # (N/m); ; 
Morison['M7N9FBzi']           = False     # (N/m); ; 
Morison['M8N1FBzi']           = False     # (N/m); ; 
Morison['M8N2FBzi']           = False     # (N/m); ; 
Morison['M8N3FBzi']           = False     # (N/m); ; 
Morison['M8N4FBzi']           = False     # (N/m); ; 
Morison['M8N5FBzi']           = False     # (N/m); ; 
Morison['M8N6FBzi']           = False     # (N/m); ; 
Morison['M8N7FBzi']           = False     # (N/m); ; 
Morison['M8N8FBzi']           = False     # (N/m); ; 
Morison['M8N9FBzi']           = False     # (N/m); ; 
Morison['M9N1FBzi']           = False     # (N/m); ; 
Morison['M9N2FBzi']           = False     # (N/m); ; 
Morison['M9N3FBzi']           = False     # (N/m); ; 
Morison['M9N4FBzi']           = False     # (N/m); ; 
Morison['M9N5FBzi']           = False     # (N/m); ; 
Morison['M9N6FBzi']           = False     # (N/m); ; 
Morison['M9N7FBzi']           = False     # (N/m); ; 
Morison['M9N8FBzi']           = False     # (N/m); ; 
Morison['M9N9FBzi']           = False     # (N/m); ; 
Morison['M1N1MBxi']           = False     # (N-m/m); x-component of the distributed bouyancy moment expressed in the inertial coordinate system; 
Morison['M1N2MBxi']           = False     # (N-m/m); ; 
Morison['M1N3MBxi']           = False     # (N-m/m); ; 
Morison['M1N4MBxi']           = False     # (N-m/m); ; 
Morison['M1N5MBxi']           = False     # (N-m/m); ; 
Morison['M1N6MBxi']           = False     # (N-m/m); ; 
Morison['M1N7MBxi']           = False     # (N-m/m); ; 
Morison['M1N8MBxi']           = False     # (N-m/m); ; 
Morison['M1N9MBxi']           = False     # (N-m/m); ; 
Morison['M2N1MBxi']           = False     # (N-m/m); ; 
Morison['M2N2MBxi']           = False     # (N-m/m); ; 
Morison['M2N3MBxi']           = False     # (N-m/m); ; 
Morison['M2N4MBxi']           = False     # (N-m/m); ; 
Morison['M2N5MBxi']           = False     # (N-m/m); ; 
Morison['M2N6MBxi']           = False     # (N-m/m); ; 
Morison['M2N7MBxi']           = False     # (N-m/m); ; 
Morison['M2N8MBxi']           = False     # (N-m/m); ; 
Morison['M2N9MBxi']           = False     # (N-m/m); ; 
Morison['M3N1MBxi']           = False     # (N-m/m); ; 
Morison['M3N2MBxi']           = False     # (N-m/m); ; 
Morison['M3N3MBxi']           = False     # (N-m/m); ; 
Morison['M3N4MBxi']           = False     # (N-m/m); ; 
Morison['M3N5MBxi']           = False     # (N-m/m); ; 
Morison['M3N6MBxi']           = False     # (N-m/m); ; 
Morison['M3N7MBxi']           = False     # (N-m/m); ; 
Morison['M3N8MBxi']           = False     # (N-m/m); ; 
Morison['M3N9MBxi']           = False     # (N-m/m); ; 
Morison['M4N1MBxi']           = False     # (N-m/m); ; 
Morison['M4N2MBxi']           = False     # (N-m/m); ; 
Morison['M4N3MBxi']           = False     # (N-m/m); ; 
Morison['M4N4MBxi']           = False     # (N-m/m); ; 
Morison['M4N5MBxi']           = False     # (N-m/m); ; 
Morison['M4N6MBxi']           = False     # (N-m/m); ; 
Morison['M4N7MBxi']           = False     # (N-m/m); ; 
Morison['M4N8MBxi']           = False     # (N-m/m); ; 
Morison['M4N9MBxi']           = False     # (N-m/m); ; 
Morison['M5N1MBxi']           = False     # (N-m/m); ; 
Morison['M5N2MBxi']           = False     # (N-m/m); ; 
Morison['M5N3MBxi']           = False     # (N-m/m); ; 
Morison['M5N4MBxi']           = False     # (N-m/m); ; 
Morison['M5N5MBxi']           = False     # (N-m/m); ; 
Morison['M5N6MBxi']           = False     # (N-m/m); ; 
Morison['M5N7MBxi']           = False     # (N-m/m); ; 
Morison['M5N8MBxi']           = False     # (N-m/m); ; 
Morison['M5N9MBxi']           = False     # (N-m/m); ; 
Morison['M6N1MBxi']           = False     # (N-m/m); ; 
Morison['M6N2MBxi']           = False     # (N-m/m); ; 
Morison['M6N3MBxi']           = False     # (N-m/m); ; 
Morison['M6N4MBxi']           = False     # (N-m/m); ; 
Morison['M6N5MBxi']           = False     # (N-m/m); ; 
Morison['M6N6MBxi']           = False     # (N-m/m); ; 
Morison['M6N7MBxi']           = False     # (N-m/m); ; 
Morison['M6N8MBxi']           = False     # (N-m/m); ; 
Morison['M6N9MBxi']           = False     # (N-m/m); ; 
Morison['M7N1MBxi']           = False     # (N-m/m); ; 
Morison['M7N2MBxi']           = False     # (N-m/m); ; 
Morison['M7N3MBxi']           = False     # (N-m/m); ; 
Morison['M7N4MBxi']           = False     # (N-m/m); ; 
Morison['M7N5MBxi']           = False     # (N-m/m); ; 
Morison['M7N6MBxi']           = False     # (N-m/m); ; 
Morison['M7N7MBxi']           = False     # (N-m/m); ; 
Morison['M7N8MBxi']           = False     # (N-m/m); ; 
Morison['M7N9MBxi']           = False     # (N-m/m); ; 
Morison['M8N1MBxi']           = False     # (N-m/m); ; 
Morison['M8N2MBxi']           = False     # (N-m/m); ; 
Morison['M8N3MBxi']           = False     # (N-m/m); ; 
Morison['M8N4MBxi']           = False     # (N-m/m); ; 
Morison['M8N5MBxi']           = False     # (N-m/m); ; 
Morison['M8N6MBxi']           = False     # (N-m/m); ; 
Morison['M8N7MBxi']           = False     # (N-m/m); ; 
Morison['M8N8MBxi']           = False     # (N-m/m); ; 
Morison['M8N9MBxi']           = False     # (N-m/m); ; 
Morison['M9N1MBxi']           = False     # (N-m/m); ; 
Morison['M9N2MBxi']           = False     # (N-m/m); ; 
Morison['M9N3MBxi']           = False     # (N-m/m); ; 
Morison['M9N4MBxi']           = False     # (N-m/m); ; 
Morison['M9N5MBxi']           = False     # (N-m/m); ; 
Morison['M9N6MBxi']           = False     # (N-m/m); ; 
Morison['M9N7MBxi']           = False     # (N-m/m); ; 
Morison['M9N8MBxi']           = False     # (N-m/m); ; 
Morison['M9N9MBxi']           = False     # (N-m/m); ; 
Morison['M1N1MByi']           = False     # (N-m/m); y-component of the distributed bouyancy moment expressed in the inertial coordinate system; 
Morison['M1N2MByi']           = False     # (N-m/m); ; 
Morison['M1N3MByi']           = False     # (N-m/m); ; 
Morison['M1N4MByi']           = False     # (N-m/m); ; 
Morison['M1N5MByi']           = False     # (N-m/m); ; 
Morison['M1N6MByi']           = False     # (N-m/m); ; 
Morison['M1N7MByi']           = False     # (N-m/m); ; 
Morison['M1N8MByi']           = False     # (N-m/m); ; 
Morison['M1N9MByi']           = False     # (N-m/m); ; 
Morison['M2N1MByi']           = False     # (N-m/m); ; 
Morison['M2N2MByi']           = False     # (N-m/m); ; 
Morison['M2N3MByi']           = False     # (N-m/m); ; 
Morison['M2N4MByi']           = False     # (N-m/m); ; 
Morison['M2N5MByi']           = False     # (N-m/m); ; 
Morison['M2N6MByi']           = False     # (N-m/m); ; 
Morison['M2N7MByi']           = False     # (N-m/m); ; 
Morison['M2N8MByi']           = False     # (N-m/m); ; 
Morison['M2N9MByi']           = False     # (N-m/m); ; 
Morison['M3N1MByi']           = False     # (N-m/m); ; 
Morison['M3N2MByi']           = False     # (N-m/m); ; 
Morison['M3N3MByi']           = False     # (N-m/m); ; 
Morison['M3N4MByi']           = False     # (N-m/m); ; 
Morison['M3N5MByi']           = False     # (N-m/m); ; 
Morison['M3N6MByi']           = False     # (N-m/m); ; 
Morison['M3N7MByi']           = False     # (N-m/m); ; 
Morison['M3N8MByi']           = False     # (N-m/m); ; 
Morison['M3N9MByi']           = False     # (N-m/m); ; 
Morison['M4N1MByi']           = False     # (N-m/m); ; 
Morison['M4N2MByi']           = False     # (N-m/m); ; 
Morison['M4N3MByi']           = False     # (N-m/m); ; 
Morison['M4N4MByi']           = False     # (N-m/m); ; 
Morison['M4N5MByi']           = False     # (N-m/m); ; 
Morison['M4N6MByi']           = False     # (N-m/m); ; 
Morison['M4N7MByi']           = False     # (N-m/m); ; 
Morison['M4N8MByi']           = False     # (N-m/m); ; 
Morison['M4N9MByi']           = False     # (N-m/m); ; 
Morison['M5N1MByi']           = False     # (N-m/m); ; 
Morison['M5N2MByi']           = False     # (N-m/m); ; 
Morison['M5N3MByi']           = False     # (N-m/m); ; 
Morison['M5N4MByi']           = False     # (N-m/m); ; 
Morison['M5N5MByi']           = False     # (N-m/m); ; 
Morison['M5N6MByi']           = False     # (N-m/m); ; 
Morison['M5N7MByi']           = False     # (N-m/m); ; 
Morison['M5N8MByi']           = False     # (N-m/m); ; 
Morison['M5N9MByi']           = False     # (N-m/m); ; 
Morison['M6N1MByi']           = False     # (N-m/m); ; 
Morison['M6N2MByi']           = False     # (N-m/m); ; 
Morison['M6N3MByi']           = False     # (N-m/m); ; 
Morison['M6N4MByi']           = False     # (N-m/m); ; 
Morison['M6N5MByi']           = False     # (N-m/m); ; 
Morison['M6N6MByi']           = False     # (N-m/m); ; 
Morison['M6N7MByi']           = False     # (N-m/m); ; 
Morison['M6N8MByi']           = False     # (N-m/m); ; 
Morison['M6N9MByi']           = False     # (N-m/m); ; 
Morison['M7N1MByi']           = False     # (N-m/m); ; 
Morison['M7N2MByi']           = False     # (N-m/m); ; 
Morison['M7N3MByi']           = False     # (N-m/m); ; 
Morison['M7N4MByi']           = False     # (N-m/m); ; 
Morison['M7N5MByi']           = False     # (N-m/m); ; 
Morison['M7N6MByi']           = False     # (N-m/m); ; 
Morison['M7N7MByi']           = False     # (N-m/m); ; 
Morison['M7N8MByi']           = False     # (N-m/m); ; 
Morison['M7N9MByi']           = False     # (N-m/m); ; 
Morison['M8N1MByi']           = False     # (N-m/m); ; 
Morison['M8N2MByi']           = False     # (N-m/m); ; 
Morison['M8N3MByi']           = False     # (N-m/m); ; 
Morison['M8N4MByi']           = False     # (N-m/m); ; 
Morison['M8N5MByi']           = False     # (N-m/m); ; 
Morison['M8N6MByi']           = False     # (N-m/m); ; 
Morison['M8N7MByi']           = False     # (N-m/m); ; 
Morison['M8N8MByi']           = False     # (N-m/m); ; 
Morison['M8N9MByi']           = False     # (N-m/m); ; 
Morison['M9N1MByi']           = False     # (N-m/m); ; 
Morison['M9N2MByi']           = False     # (N-m/m); ; 
Morison['M9N3MByi']           = False     # (N-m/m); ; 
Morison['M9N4MByi']           = False     # (N-m/m); ; 
Morison['M9N5MByi']           = False     # (N-m/m); ; 
Morison['M9N6MByi']           = False     # (N-m/m); ; 
Morison['M9N7MByi']           = False     # (N-m/m); ; 
Morison['M9N8MByi']           = False     # (N-m/m); ; 
Morison['M9N9MByi']           = False     # (N-m/m); ; 
Morison['M1N1MBzi']           = False     # (N-m/m); z-component of the distributed bouyancy moment expressed in the inertial coordinate system; 
Morison['M1N2MBzi']           = False     # (N-m/m); ; 
Morison['M1N3MBzi']           = False     # (N-m/m); ; 
Morison['M1N4MBzi']           = False     # (N-m/m); ; 
Morison['M1N5MBzi']           = False     # (N-m/m); ; 
Morison['M1N6MBzi']           = False     # (N-m/m); ; 
Morison['M1N7MBzi']           = False     # (N-m/m); ; 
Morison['M1N8MBzi']           = False     # (N-m/m); ; 
Morison['M1N9MBzi']           = False     # (N-m/m); ; 
Morison['M2N1MBzi']           = False     # (N-m/m); ; 
Morison['M2N2MBzi']           = False     # (N-m/m); ; 
Morison['M2N3MBzi']           = False     # (N-m/m); ; 
Morison['M2N4MBzi']           = False     # (N-m/m); ; 
Morison['M2N5MBzi']           = False     # (N-m/m); ; 
Morison['M2N6MBzi']           = False     # (N-m/m); ; 
Morison['M2N7MBzi']           = False     # (N-m/m); ; 
Morison['M2N8MBzi']           = False     # (N-m/m); ; 
Morison['M2N9MBzi']           = False     # (N-m/m); ; 
Morison['M3N1MBzi']           = False     # (N-m/m); ; 
Morison['M3N2MBzi']           = False     # (N-m/m); ; 
Morison['M3N3MBzi']           = False     # (N-m/m); ; 
Morison['M3N4MBzi']           = False     # (N-m/m); ; 
Morison['M3N5MBzi']           = False     # (N-m/m); ; 
Morison['M3N6MBzi']           = False     # (N-m/m); ; 
Morison['M3N7MBzi']           = False     # (N-m/m); ; 
Morison['M3N8MBzi']           = False     # (N-m/m); ; 
Morison['M3N9MBzi']           = False     # (N-m/m); ; 
Morison['M4N1MBzi']           = False     # (N-m/m); ; 
Morison['M4N2MBzi']           = False     # (N-m/m); ; 
Morison['M4N3MBzi']           = False     # (N-m/m); ; 
Morison['M4N4MBzi']           = False     # (N-m/m); ; 
Morison['M4N5MBzi']           = False     # (N-m/m); ; 
Morison['M4N6MBzi']           = False     # (N-m/m); ; 
Morison['M4N7MBzi']           = False     # (N-m/m); ; 
Morison['M4N8MBzi']           = False     # (N-m/m); ; 
Morison['M4N9MBzi']           = False     # (N-m/m); ; 
Morison['M5N1MBzi']           = False     # (N-m/m); ; 
Morison['M5N2MBzi']           = False     # (N-m/m); ; 
Morison['M5N3MBzi']           = False     # (N-m/m); ; 
Morison['M5N4MBzi']           = False     # (N-m/m); ; 
Morison['M5N5MBzi']           = False     # (N-m/m); ; 
Morison['M5N6MBzi']           = False     # (N-m/m); ; 
Morison['M5N7MBzi']           = False     # (N-m/m); ; 
Morison['M5N8MBzi']           = False     # (N-m/m); ; 
Morison['M5N9MBzi']           = False     # (N-m/m); ; 
Morison['M6N1MBzi']           = False     # (N-m/m); ; 
Morison['M6N2MBzi']           = False     # (N-m/m); ; 
Morison['M6N3MBzi']           = False     # (N-m/m); ; 
Morison['M6N4MBzi']           = False     # (N-m/m); ; 
Morison['M6N5MBzi']           = False     # (N-m/m); ; 
Morison['M6N6MBzi']           = False     # (N-m/m); ; 
Morison['M6N7MBzi']           = False     # (N-m/m); ; 
Morison['M6N8MBzi']           = False     # (N-m/m); ; 
Morison['M6N9MBzi']           = False     # (N-m/m); ; 
Morison['M7N1MBzi']           = False     # (N-m/m); ; 
Morison['M7N2MBzi']           = False     # (N-m/m); ; 
Morison['M7N3MBzi']           = False     # (N-m/m); ; 
Morison['M7N4MBzi']           = False     # (N-m/m); ; 
Morison['M7N5MBzi']           = False     # (N-m/m); ; 
Morison['M7N6MBzi']           = False     # (N-m/m); ; 
Morison['M7N7MBzi']           = False     # (N-m/m); ; 
Morison['M7N8MBzi']           = False     # (N-m/m); ; 
Morison['M7N9MBzi']           = False     # (N-m/m); ; 
Morison['M8N1MBzi']           = False     # (N-m/m); ; 
Morison['M8N2MBzi']           = False     # (N-m/m); ; 
Morison['M8N3MBzi']           = False     # (N-m/m); ; 
Morison['M8N4MBzi']           = False     # (N-m/m); ; 
Morison['M8N5MBzi']           = False     # (N-m/m); ; 
Morison['M8N6MBzi']           = False     # (N-m/m); ; 
Morison['M8N7MBzi']           = False     # (N-m/m); ; 
Morison['M8N8MBzi']           = False     # (N-m/m); ; 
Morison['M8N9MBzi']           = False     # (N-m/m); ; 
Morison['M9N1MBzi']           = False     # (N-m/m); ; 
Morison['M9N2MBzi']           = False     # (N-m/m); ; 
Morison['M9N3MBzi']           = False     # (N-m/m); ; 
Morison['M9N4MBzi']           = False     # (N-m/m); ; 
Morison['M9N5MBzi']           = False     # (N-m/m); ; 
Morison['M9N6MBzi']           = False     # (N-m/m); ; 
Morison['M9N7MBzi']           = False     # (N-m/m); ; 
Morison['M9N8MBzi']           = False     # (N-m/m); ; 
Morison['M9N9MBzi']           = False     # (N-m/m); ; 
Morison['M1N1FBFxi']          = False     # (N/m); x-component of the distributed filled fluid bouyancy force expressed in the inertial coordinate system; 
Morison['M1N2FBFxi']          = False     # (N/m); ; 
Morison['M1N3FBFxi']          = False     # (N/m); ; 
Morison['M1N4FBFxi']          = False     # (N/m); ; 
Morison['M1N5FBFxi']          = False     # (N/m); ; 
Morison['M1N6FBFxi']          = False     # (N/m); ; 
Morison['M1N7FBFxi']          = False     # (N/m); ; 
Morison['M1N8FBFxi']          = False     # (N/m); ; 
Morison['M1N9FBFxi']          = False     # (N/m); ; 
Morison['M2N1FBFxi']          = False     # (N/m); ; 
Morison['M2N2FBFxi']          = False     # (N/m); ; 
Morison['M2N3FBFxi']          = False     # (N/m); ; 
Morison['M2N4FBFxi']          = False     # (N/m); ; 
Morison['M2N5FBFxi']          = False     # (N/m); ; 
Morison['M2N6FBFxi']          = False     # (N/m); ; 
Morison['M2N7FBFxi']          = False     # (N/m); ; 
Morison['M2N8FBFxi']          = False     # (N/m); ; 
Morison['M2N9FBFxi']          = False     # (N/m); ; 
Morison['M3N1FBFxi']          = False     # (N/m); ; 
Morison['M3N2FBFxi']          = False     # (N/m); ; 
Morison['M3N3FBFxi']          = False     # (N/m); ; 
Morison['M3N4FBFxi']          = False     # (N/m); ; 
Morison['M3N5FBFxi']          = False     # (N/m); ; 
Morison['M3N6FBFxi']          = False     # (N/m); ; 
Morison['M3N7FBFxi']          = False     # (N/m); ; 
Morison['M3N8FBFxi']          = False     # (N/m); ; 
Morison['M3N9FBFxi']          = False     # (N/m); ; 
Morison['M4N1FBFxi']          = False     # (N/m); ; 
Morison['M4N2FBFxi']          = False     # (N/m); ; 
Morison['M4N3FBFxi']          = False     # (N/m); ; 
Morison['M4N4FBFxi']          = False     # (N/m); ; 
Morison['M4N5FBFxi']          = False     # (N/m); ; 
Morison['M4N6FBFxi']          = False     # (N/m); ; 
Morison['M4N7FBFxi']          = False     # (N/m); ; 
Morison['M4N8FBFxi']          = False     # (N/m); ; 
Morison['M4N9FBFxi']          = False     # (N/m); ; 
Morison['M5N1FBFxi']          = False     # (N/m); ; 
Morison['M5N2FBFxi']          = False     # (N/m); ; 
Morison['M5N3FBFxi']          = False     # (N/m); ; 
Morison['M5N4FBFxi']          = False     # (N/m); ; 
Morison['M5N5FBFxi']          = False     # (N/m); ; 
Morison['M5N6FBFxi']          = False     # (N/m); ; 
Morison['M5N7FBFxi']          = False     # (N/m); ; 
Morison['M5N8FBFxi']          = False     # (N/m); ; 
Morison['M5N9FBFxi']          = False     # (N/m); ; 
Morison['M6N1FBFxi']          = False     # (N/m); ; 
Morison['M6N2FBFxi']          = False     # (N/m); ; 
Morison['M6N3FBFxi']          = False     # (N/m); ; 
Morison['M6N4FBFxi']          = False     # (N/m); ; 
Morison['M6N5FBFxi']          = False     # (N/m); ; 
Morison['M6N6FBFxi']          = False     # (N/m); ; 
Morison['M6N7FBFxi']          = False     # (N/m); ; 
Morison['M6N8FBFxi']          = False     # (N/m); ; 
Morison['M6N9FBFxi']          = False     # (N/m); ; 
Morison['M7N1FBFxi']          = False     # (N/m); ; 
Morison['M7N2FBFxi']          = False     # (N/m); ; 
Morison['M7N3FBFxi']          = False     # (N/m); ; 
Morison['M7N4FBFxi']          = False     # (N/m); ; 
Morison['M7N5FBFxi']          = False     # (N/m); ; 
Morison['M7N6FBFxi']          = False     # (N/m); ; 
Morison['M7N7FBFxi']          = False     # (N/m); ; 
Morison['M7N8FBFxi']          = False     # (N/m); ; 
Morison['M7N9FBFxi']          = False     # (N/m); ; 
Morison['M8N1FBFxi']          = False     # (N/m); ; 
Morison['M8N2FBFxi']          = False     # (N/m); ; 
Morison['M8N3FBFxi']          = False     # (N/m); ; 
Morison['M8N4FBFxi']          = False     # (N/m); ; 
Morison['M8N5FBFxi']          = False     # (N/m); ; 
Morison['M8N6FBFxi']          = False     # (N/m); ; 
Morison['M8N7FBFxi']          = False     # (N/m); ; 
Morison['M8N8FBFxi']          = False     # (N/m); ; 
Morison['M8N9FBFxi']          = False     # (N/m); ; 
Morison['M9N1FBFxi']          = False     # (N/m); ; 
Morison['M9N2FBFxi']          = False     # (N/m); ; 
Morison['M9N3FBFxi']          = False     # (N/m); ; 
Morison['M9N4FBFxi']          = False     # (N/m); ; 
Morison['M9N5FBFxi']          = False     # (N/m); ; 
Morison['M9N6FBFxi']          = False     # (N/m); ; 
Morison['M9N7FBFxi']          = False     # (N/m); ; 
Morison['M9N8FBFxi']          = False     # (N/m); ; 
Morison['M9N9FBFxi']          = False     # (N/m); ; 
Morison['M1N1FBFyi']          = False     # (N/m); y-component of the distributed filled fluid bouyancy force expressed in the inertial coordinate system; 
Morison['M1N2FBFyi']          = False     # (N/m); ; 
Morison['M1N3FBFyi']          = False     # (N/m); ; 
Morison['M1N4FBFyi']          = False     # (N/m); ; 
Morison['M1N5FBFyi']          = False     # (N/m); ; 
Morison['M1N6FBFyi']          = False     # (N/m); ; 
Morison['M1N7FBFyi']          = False     # (N/m); ; 
Morison['M1N8FBFyi']          = False     # (N/m); ; 
Morison['M1N9FBFyi']          = False     # (N/m); ; 
Morison['M2N1FBFyi']          = False     # (N/m); ; 
Morison['M2N2FBFyi']          = False     # (N/m); ; 
Morison['M2N3FBFyi']          = False     # (N/m); ; 
Morison['M2N4FBFyi']          = False     # (N/m); ; 
Morison['M2N5FBFyi']          = False     # (N/m); ; 
Morison['M2N6FBFyi']          = False     # (N/m); ; 
Morison['M2N7FBFyi']          = False     # (N/m); ; 
Morison['M2N8FBFyi']          = False     # (N/m); ; 
Morison['M2N9FBFyi']          = False     # (N/m); ; 
Morison['M3N1FBFyi']          = False     # (N/m); ; 
Morison['M3N2FBFyi']          = False     # (N/m); ; 
Morison['M3N3FBFyi']          = False     # (N/m); ; 
Morison['M3N4FBFyi']          = False     # (N/m); ; 
Morison['M3N5FBFyi']          = False     # (N/m); ; 
Morison['M3N6FBFyi']          = False     # (N/m); ; 
Morison['M3N7FBFyi']          = False     # (N/m); ; 
Morison['M3N8FBFyi']          = False     # (N/m); ; 
Morison['M3N9FBFyi']          = False     # (N/m); ; 
Morison['M4N1FBFyi']          = False     # (N/m); ; 
Morison['M4N2FBFyi']          = False     # (N/m); ; 
Morison['M4N3FBFyi']          = False     # (N/m); ; 
Morison['M4N4FBFyi']          = False     # (N/m); ; 
Morison['M4N5FBFyi']          = False     # (N/m); ; 
Morison['M4N6FBFyi']          = False     # (N/m); ; 
Morison['M4N7FBFyi']          = False     # (N/m); ; 
Morison['M4N8FBFyi']          = False     # (N/m); ; 
Morison['M4N9FBFyi']          = False     # (N/m); ; 
Morison['M5N1FBFyi']          = False     # (N/m); ; 
Morison['M5N2FBFyi']          = False     # (N/m); ; 
Morison['M5N3FBFyi']          = False     # (N/m); ; 
Morison['M5N4FBFyi']          = False     # (N/m); ; 
Morison['M5N5FBFyi']          = False     # (N/m); ; 
Morison['M5N6FBFyi']          = False     # (N/m); ; 
Morison['M5N7FBFyi']          = False     # (N/m); ; 
Morison['M5N8FBFyi']          = False     # (N/m); ; 
Morison['M5N9FBFyi']          = False     # (N/m); ; 
Morison['M6N1FBFyi']          = False     # (N/m); ; 
Morison['M6N2FBFyi']          = False     # (N/m); ; 
Morison['M6N3FBFyi']          = False     # (N/m); ; 
Morison['M6N4FBFyi']          = False     # (N/m); ; 
Morison['M6N5FBFyi']          = False     # (N/m); ; 
Morison['M6N6FBFyi']          = False     # (N/m); ; 
Morison['M6N7FBFyi']          = False     # (N/m); ; 
Morison['M6N8FBFyi']          = False     # (N/m); ; 
Morison['M6N9FBFyi']          = False     # (N/m); ; 
Morison['M7N1FBFyi']          = False     # (N/m); ; 
Morison['M7N2FBFyi']          = False     # (N/m); ; 
Morison['M7N3FBFyi']          = False     # (N/m); ; 
Morison['M7N4FBFyi']          = False     # (N/m); ; 
Morison['M7N5FBFyi']          = False     # (N/m); ; 
Morison['M7N6FBFyi']          = False     # (N/m); ; 
Morison['M7N7FBFyi']          = False     # (N/m); ; 
Morison['M7N8FBFyi']          = False     # (N/m); ; 
Morison['M7N9FBFyi']          = False     # (N/m); ; 
Morison['M8N1FBFyi']          = False     # (N/m); ; 
Morison['M8N2FBFyi']          = False     # (N/m); ; 
Morison['M8N3FBFyi']          = False     # (N/m); ; 
Morison['M8N4FBFyi']          = False     # (N/m); ; 
Morison['M8N5FBFyi']          = False     # (N/m); ; 
Morison['M8N6FBFyi']          = False     # (N/m); ; 
Morison['M8N7FBFyi']          = False     # (N/m); ; 
Morison['M8N8FBFyi']          = False     # (N/m); ; 
Morison['M8N9FBFyi']          = False     # (N/m); ; 
Morison['M9N1FBFyi']          = False     # (N/m); ; 
Morison['M9N2FBFyi']          = False     # (N/m); ; 
Morison['M9N3FBFyi']          = False     # (N/m); ; 
Morison['M9N4FBFyi']          = False     # (N/m); ; 
Morison['M9N5FBFyi']          = False     # (N/m); ; 
Morison['M9N6FBFyi']          = False     # (N/m); ; 
Morison['M9N7FBFyi']          = False     # (N/m); ; 
Morison['M9N8FBFyi']          = False     # (N/m); ; 
Morison['M9N9FBFyi']          = False     # (N/m); ; 
Morison['M1N1FBFzi']          = False     # (N/m); z-component of the distributed filled fluid bouyancy force expressed in the inertial coordinate system; 
Morison['M1N2FBFzi']          = False     # (N/m); ; 
Morison['M1N3FBFzi']          = False     # (N/m); ; 
Morison['M1N4FBFzi']          = False     # (N/m); ; 
Morison['M1N5FBFzi']          = False     # (N/m); ; 
Morison['M1N6FBFzi']          = False     # (N/m); ; 
Morison['M1N7FBFzi']          = False     # (N/m); ; 
Morison['M1N8FBFzi']          = False     # (N/m); ; 
Morison['M1N9FBFzi']          = False     # (N/m); ; 
Morison['M2N1FBFzi']          = False     # (N/m); ; 
Morison['M2N2FBFzi']          = False     # (N/m); ; 
Morison['M2N3FBFzi']          = False     # (N/m); ; 
Morison['M2N4FBFzi']          = False     # (N/m); ; 
Morison['M2N5FBFzi']          = False     # (N/m); ; 
Morison['M2N6FBFzi']          = False     # (N/m); ; 
Morison['M2N7FBFzi']          = False     # (N/m); ; 
Morison['M2N8FBFzi']          = False     # (N/m); ; 
Morison['M2N9FBFzi']          = False     # (N/m); ; 
Morison['M3N1FBFzi']          = False     # (N/m); ; 
Morison['M3N2FBFzi']          = False     # (N/m); ; 
Morison['M3N3FBFzi']          = False     # (N/m); ; 
Morison['M3N4FBFzi']          = False     # (N/m); ; 
Morison['M3N5FBFzi']          = False     # (N/m); ; 
Morison['M3N6FBFzi']          = False     # (N/m); ; 
Morison['M3N7FBFzi']          = False     # (N/m); ; 
Morison['M3N8FBFzi']          = False     # (N/m); ; 
Morison['M3N9FBFzi']          = False     # (N/m); ; 
Morison['M4N1FBFzi']          = False     # (N/m); ; 
Morison['M4N2FBFzi']          = False     # (N/m); ; 
Morison['M4N3FBFzi']          = False     # (N/m); ; 
Morison['M4N4FBFzi']          = False     # (N/m); ; 
Morison['M4N5FBFzi']          = False     # (N/m); ; 
Morison['M4N6FBFzi']          = False     # (N/m); ; 
Morison['M4N7FBFzi']          = False     # (N/m); ; 
Morison['M4N8FBFzi']          = False     # (N/m); ; 
Morison['M4N9FBFzi']          = False     # (N/m); ; 
Morison['M5N1FBFzi']          = False     # (N/m); ; 
Morison['M5N2FBFzi']          = False     # (N/m); ; 
Morison['M5N3FBFzi']          = False     # (N/m); ; 
Morison['M5N4FBFzi']          = False     # (N/m); ; 
Morison['M5N5FBFzi']          = False     # (N/m); ; 
Morison['M5N6FBFzi']          = False     # (N/m); ; 
Morison['M5N7FBFzi']          = False     # (N/m); ; 
Morison['M5N8FBFzi']          = False     # (N/m); ; 
Morison['M5N9FBFzi']          = False     # (N/m); ; 
Morison['M6N1FBFzi']          = False     # (N/m); ; 
Morison['M6N2FBFzi']          = False     # (N/m); ; 
Morison['M6N3FBFzi']          = False     # (N/m); ; 
Morison['M6N4FBFzi']          = False     # (N/m); ; 
Morison['M6N5FBFzi']          = False     # (N/m); ; 
Morison['M6N6FBFzi']          = False     # (N/m); ; 
Morison['M6N7FBFzi']          = False     # (N/m); ; 
Morison['M6N8FBFzi']          = False     # (N/m); ; 
Morison['M6N9FBFzi']          = False     # (N/m); ; 
Morison['M7N1FBFzi']          = False     # (N/m); ; 
Morison['M7N2FBFzi']          = False     # (N/m); ; 
Morison['M7N3FBFzi']          = False     # (N/m); ; 
Morison['M7N4FBFzi']          = False     # (N/m); ; 
Morison['M7N5FBFzi']          = False     # (N/m); ; 
Morison['M7N6FBFzi']          = False     # (N/m); ; 
Morison['M7N7FBFzi']          = False     # (N/m); ; 
Morison['M7N8FBFzi']          = False     # (N/m); ; 
Morison['M7N9FBFzi']          = False     # (N/m); ; 
Morison['M8N1FBFzi']          = False     # (N/m); ; 
Morison['M8N2FBFzi']          = False     # (N/m); ; 
Morison['M8N3FBFzi']          = False     # (N/m); ; 
Morison['M8N4FBFzi']          = False     # (N/m); ; 
Morison['M8N5FBFzi']          = False     # (N/m); ; 
Morison['M8N6FBFzi']          = False     # (N/m); ; 
Morison['M8N7FBFzi']          = False     # (N/m); ; 
Morison['M8N8FBFzi']          = False     # (N/m); ; 
Morison['M8N9FBFzi']          = False     # (N/m); ; 
Morison['M9N1FBFzi']          = False     # (N/m); ; 
Morison['M9N2FBFzi']          = False     # (N/m); ; 
Morison['M9N3FBFzi']          = False     # (N/m); ; 
Morison['M9N4FBFzi']          = False     # (N/m); ; 
Morison['M9N5FBFzi']          = False     # (N/m); ; 
Morison['M9N6FBFzi']          = False     # (N/m); ; 
Morison['M9N7FBFzi']          = False     # (N/m); ; 
Morison['M9N8FBFzi']          = False     # (N/m); ; 
Morison['M9N9FBFzi']          = False     # (N/m); ; 
Morison['M1N1MBFxi']          = False     # (N-m/m); x-component of the distributed filled fluid bouyancy moment expressed in the inertial coordinate system; 
Morison['M1N2MBFxi']          = False     # (N-m/m); ; 
Morison['M1N3MBFxi']          = False     # (N-m/m); ; 
Morison['M1N4MBFxi']          = False     # (N-m/m); ; 
Morison['M1N5MBFxi']          = False     # (N-m/m); ; 
Morison['M1N6MBFxi']          = False     # (N-m/m); ; 
Morison['M1N7MBFxi']          = False     # (N-m/m); ; 
Morison['M1N8MBFxi']          = False     # (N-m/m); ; 
Morison['M1N9MBFxi']          = False     # (N-m/m); ; 
Morison['M2N1MBFxi']          = False     # (N-m/m); ; 
Morison['M2N2MBFxi']          = False     # (N-m/m); ; 
Morison['M2N3MBFxi']          = False     # (N-m/m); ; 
Morison['M2N4MBFxi']          = False     # (N-m/m); ; 
Morison['M2N5MBFxi']          = False     # (N-m/m); ; 
Morison['M2N6MBFxi']          = False     # (N-m/m); ; 
Morison['M2N7MBFxi']          = False     # (N-m/m); ; 
Morison['M2N8MBFxi']          = False     # (N-m/m); ; 
Morison['M2N9MBFxi']          = False     # (N-m/m); ; 
Morison['M3N1MBFxi']          = False     # (N-m/m); ; 
Morison['M3N2MBFxi']          = False     # (N-m/m); ; 
Morison['M3N3MBFxi']          = False     # (N-m/m); ; 
Morison['M3N4MBFxi']          = False     # (N-m/m); ; 
Morison['M3N5MBFxi']          = False     # (N-m/m); ; 
Morison['M3N6MBFxi']          = False     # (N-m/m); ; 
Morison['M3N7MBFxi']          = False     # (N-m/m); ; 
Morison['M3N8MBFxi']          = False     # (N-m/m); ; 
Morison['M3N9MBFxi']          = False     # (N-m/m); ; 
Morison['M4N1MBFxi']          = False     # (N-m/m); ; 
Morison['M4N2MBFxi']          = False     # (N-m/m); ; 
Morison['M4N3MBFxi']          = False     # (N-m/m); ; 
Morison['M4N4MBFxi']          = False     # (N-m/m); ; 
Morison['M4N5MBFxi']          = False     # (N-m/m); ; 
Morison['M4N6MBFxi']          = False     # (N-m/m); ; 
Morison['M4N7MBFxi']          = False     # (N-m/m); ; 
Morison['M4N8MBFxi']          = False     # (N-m/m); ; 
Morison['M4N9MBFxi']          = False     # (N-m/m); ; 
Morison['M5N1MBFxi']          = False     # (N-m/m); ; 
Morison['M5N2MBFxi']          = False     # (N-m/m); ; 
Morison['M5N3MBFxi']          = False     # (N-m/m); ; 
Morison['M5N4MBFxi']          = False     # (N-m/m); ; 
Morison['M5N5MBFxi']          = False     # (N-m/m); ; 
Morison['M5N6MBFxi']          = False     # (N-m/m); ; 
Morison['M5N7MBFxi']          = False     # (N-m/m); ; 
Morison['M5N8MBFxi']          = False     # (N-m/m); ; 
Morison['M5N9MBFxi']          = False     # (N-m/m); ; 
Morison['M6N1MBFxi']          = False     # (N-m/m); ; 
Morison['M6N2MBFxi']          = False     # (N-m/m); ; 
Morison['M6N3MBFxi']          = False     # (N-m/m); ; 
Morison['M6N4MBFxi']          = False     # (N-m/m); ; 
Morison['M6N5MBFxi']          = False     # (N-m/m); ; 
Morison['M6N6MBFxi']          = False     # (N-m/m); ; 
Morison['M6N7MBFxi']          = False     # (N-m/m); ; 
Morison['M6N8MBFxi']          = False     # (N-m/m); ; 
Morison['M6N9MBFxi']          = False     # (N-m/m); ; 
Morison['M7N1MBFxi']          = False     # (N-m/m); ; 
Morison['M7N2MBFxi']          = False     # (N-m/m); ; 
Morison['M7N3MBFxi']          = False     # (N-m/m); ; 
Morison['M7N4MBFxi']          = False     # (N-m/m); ; 
Morison['M7N5MBFxi']          = False     # (N-m/m); ; 
Morison['M7N6MBFxi']          = False     # (N-m/m); ; 
Morison['M7N7MBFxi']          = False     # (N-m/m); ; 
Morison['M7N8MBFxi']          = False     # (N-m/m); ; 
Morison['M7N9MBFxi']          = False     # (N-m/m); ; 
Morison['M8N1MBFxi']          = False     # (N-m/m); ; 
Morison['M8N2MBFxi']          = False     # (N-m/m); ; 
Morison['M8N3MBFxi']          = False     # (N-m/m); ; 
Morison['M8N4MBFxi']          = False     # (N-m/m); ; 
Morison['M8N5MBFxi']          = False     # (N-m/m); ; 
Morison['M8N6MBFxi']          = False     # (N-m/m); ; 
Morison['M8N7MBFxi']          = False     # (N-m/m); ; 
Morison['M8N8MBFxi']          = False     # (N-m/m); ; 
Morison['M8N9MBFxi']          = False     # (N-m/m); ; 
Morison['M9N1MBFxi']          = False     # (N-m/m); ; 
Morison['M9N2MBFxi']          = False     # (N-m/m); ; 
Morison['M9N3MBFxi']          = False     # (N-m/m); ; 
Morison['M9N4MBFxi']          = False     # (N-m/m); ; 
Morison['M9N5MBFxi']          = False     # (N-m/m); ; 
Morison['M9N6MBFxi']          = False     # (N-m/m); ; 
Morison['M9N7MBFxi']          = False     # (N-m/m); ; 
Morison['M9N8MBFxi']          = False     # (N-m/m); ; 
Morison['M9N9MBFxi']          = False     # (N-m/m); ; 
Morison['M1N1MBFyi']          = False     # (N-m/m); y-component of the distributed filled fluid bouyancy moment expressed in the inertial coordinate system; 
Morison['M1N2MBFyi']          = False     # (N-m/m); ; 
Morison['M1N3MBFyi']          = False     # (N-m/m); ; 
Morison['M1N4MBFyi']          = False     # (N-m/m); ; 
Morison['M1N5MBFyi']          = False     # (N-m/m); ; 
Morison['M1N6MBFyi']          = False     # (N-m/m); ; 
Morison['M1N7MBFyi']          = False     # (N-m/m); ; 
Morison['M1N8MBFyi']          = False     # (N-m/m); ; 
Morison['M1N9MBFyi']          = False     # (N-m/m); ; 
Morison['M2N1MBFyi']          = False     # (N-m/m); ; 
Morison['M2N2MBFyi']          = False     # (N-m/m); ; 
Morison['M2N3MBFyi']          = False     # (N-m/m); ; 
Morison['M2N4MBFyi']          = False     # (N-m/m); ; 
Morison['M2N5MBFyi']          = False     # (N-m/m); ; 
Morison['M2N6MBFyi']          = False     # (N-m/m); ; 
Morison['M2N7MBFyi']          = False     # (N-m/m); ; 
Morison['M2N8MBFyi']          = False     # (N-m/m); ; 
Morison['M2N9MBFyi']          = False     # (N-m/m); ; 
Morison['M3N1MBFyi']          = False     # (N-m/m); ; 
Morison['M3N2MBFyi']          = False     # (N-m/m); ; 
Morison['M3N3MBFyi']          = False     # (N-m/m); ; 
Morison['M3N4MBFyi']          = False     # (N-m/m); ; 
Morison['M3N5MBFyi']          = False     # (N-m/m); ; 
Morison['M3N6MBFyi']          = False     # (N-m/m); ; 
Morison['M3N7MBFyi']          = False     # (N-m/m); ; 
Morison['M3N8MBFyi']          = False     # (N-m/m); ; 
Morison['M3N9MBFyi']          = False     # (N-m/m); ; 
Morison['M4N1MBFyi']          = False     # (N-m/m); ; 
Morison['M4N2MBFyi']          = False     # (N-m/m); ; 
Morison['M4N3MBFyi']          = False     # (N-m/m); ; 
Morison['M4N4MBFyi']          = False     # (N-m/m); ; 
Morison['M4N5MBFyi']          = False     # (N-m/m); ; 
Morison['M4N6MBFyi']          = False     # (N-m/m); ; 
Morison['M4N7MBFyi']          = False     # (N-m/m); ; 
Morison['M4N8MBFyi']          = False     # (N-m/m); ; 
Morison['M4N9MBFyi']          = False     # (N-m/m); ; 
Morison['M5N1MBFyi']          = False     # (N-m/m); ; 
Morison['M5N2MBFyi']          = False     # (N-m/m); ; 
Morison['M5N3MBFyi']          = False     # (N-m/m); ; 
Morison['M5N4MBFyi']          = False     # (N-m/m); ; 
Morison['M5N5MBFyi']          = False     # (N-m/m); ; 
Morison['M5N6MBFyi']          = False     # (N-m/m); ; 
Morison['M5N7MBFyi']          = False     # (N-m/m); ; 
Morison['M5N8MBFyi']          = False     # (N-m/m); ; 
Morison['M5N9MBFyi']          = False     # (N-m/m); ; 
Morison['M6N1MBFyi']          = False     # (N-m/m); ; 
Morison['M6N2MBFyi']          = False     # (N-m/m); ; 
Morison['M6N3MBFyi']          = False     # (N-m/m); ; 
Morison['M6N4MBFyi']          = False     # (N-m/m); ; 
Morison['M6N5MBFyi']          = False     # (N-m/m); ; 
Morison['M6N6MBFyi']          = False     # (N-m/m); ; 
Morison['M6N7MBFyi']          = False     # (N-m/m); ; 
Morison['M6N8MBFyi']          = False     # (N-m/m); ; 
Morison['M6N9MBFyi']          = False     # (N-m/m); ; 
Morison['M7N1MBFyi']          = False     # (N-m/m); ; 
Morison['M7N2MBFyi']          = False     # (N-m/m); ; 
Morison['M7N3MBFyi']          = False     # (N-m/m); ; 
Morison['M7N4MBFyi']          = False     # (N-m/m); ; 
Morison['M7N5MBFyi']          = False     # (N-m/m); ; 
Morison['M7N6MBFyi']          = False     # (N-m/m); ; 
Morison['M7N7MBFyi']          = False     # (N-m/m); ; 
Morison['M7N8MBFyi']          = False     # (N-m/m); ; 
Morison['M7N9MBFyi']          = False     # (N-m/m); ; 
Morison['M8N1MBFyi']          = False     # (N-m/m); ; 
Morison['M8N2MBFyi']          = False     # (N-m/m); ; 
Morison['M8N3MBFyi']          = False     # (N-m/m); ; 
Morison['M8N4MBFyi']          = False     # (N-m/m); ; 
Morison['M8N5MBFyi']          = False     # (N-m/m); ; 
Morison['M8N6MBFyi']          = False     # (N-m/m); ; 
Morison['M8N7MBFyi']          = False     # (N-m/m); ; 
Morison['M8N8MBFyi']          = False     # (N-m/m); ; 
Morison['M8N9MBFyi']          = False     # (N-m/m); ; 
Morison['M9N1MBFyi']          = False     # (N-m/m); ; 
Morison['M9N2MBFyi']          = False     # (N-m/m); ; 
Morison['M9N3MBFyi']          = False     # (N-m/m); ; 
Morison['M9N4MBFyi']          = False     # (N-m/m); ; 
Morison['M9N5MBFyi']          = False     # (N-m/m); ; 
Morison['M9N6MBFyi']          = False     # (N-m/m); ; 
Morison['M9N7MBFyi']          = False     # (N-m/m); ; 
Morison['M9N8MBFyi']          = False     # (N-m/m); ; 
Morison['M9N9MBFyi']          = False     # (N-m/m); ; 
Morison['M1N1MBFzi']          = False     # (N-m/m); z-component of the distributed filled fluid bouyancy moment expressed in the inertial coordinate system; 
Morison['M1N2MBFzi']          = False     # (N-m/m); ; 
Morison['M1N3MBFzi']          = False     # (N-m/m); ; 
Morison['M1N4MBFzi']          = False     # (N-m/m); ; 
Morison['M1N5MBFzi']          = False     # (N-m/m); ; 
Morison['M1N6MBFzi']          = False     # (N-m/m); ; 
Morison['M1N7MBFzi']          = False     # (N-m/m); ; 
Morison['M1N8MBFzi']          = False     # (N-m/m); ; 
Morison['M1N9MBFzi']          = False     # (N-m/m); ; 
Morison['M2N1MBFzi']          = False     # (N-m/m); ; 
Morison['M2N2MBFzi']          = False     # (N-m/m); ; 
Morison['M2N3MBFzi']          = False     # (N-m/m); ; 
Morison['M2N4MBFzi']          = False     # (N-m/m); ; 
Morison['M2N5MBFzi']          = False     # (N-m/m); ; 
Morison['M2N6MBFzi']          = False     # (N-m/m); ; 
Morison['M2N7MBFzi']          = False     # (N-m/m); ; 
Morison['M2N8MBFzi']          = False     # (N-m/m); ; 
Morison['M2N9MBFzi']          = False     # (N-m/m); ; 
Morison['M3N1MBFzi']          = False     # (N-m/m); ; 
Morison['M3N2MBFzi']          = False     # (N-m/m); ; 
Morison['M3N3MBFzi']          = False     # (N-m/m); ; 
Morison['M3N4MBFzi']          = False     # (N-m/m); ; 
Morison['M3N5MBFzi']          = False     # (N-m/m); ; 
Morison['M3N6MBFzi']          = False     # (N-m/m); ; 
Morison['M3N7MBFzi']          = False     # (N-m/m); ; 
Morison['M3N8MBFzi']          = False     # (N-m/m); ; 
Morison['M3N9MBFzi']          = False     # (N-m/m); ; 
Morison['M4N1MBFzi']          = False     # (N-m/m); ; 
Morison['M4N2MBFzi']          = False     # (N-m/m); ; 
Morison['M4N3MBFzi']          = False     # (N-m/m); ; 
Morison['M4N4MBFzi']          = False     # (N-m/m); ; 
Morison['M4N5MBFzi']          = False     # (N-m/m); ; 
Morison['M4N6MBFzi']          = False     # (N-m/m); ; 
Morison['M4N7MBFzi']          = False     # (N-m/m); ; 
Morison['M4N8MBFzi']          = False     # (N-m/m); ; 
Morison['M4N9MBFzi']          = False     # (N-m/m); ; 
Morison['M5N1MBFzi']          = False     # (N-m/m); ; 
Morison['M5N2MBFzi']          = False     # (N-m/m); ; 
Morison['M5N3MBFzi']          = False     # (N-m/m); ; 
Morison['M5N4MBFzi']          = False     # (N-m/m); ; 
Morison['M5N5MBFzi']          = False     # (N-m/m); ; 
Morison['M5N6MBFzi']          = False     # (N-m/m); ; 
Morison['M5N7MBFzi']          = False     # (N-m/m); ; 
Morison['M5N8MBFzi']          = False     # (N-m/m); ; 
Morison['M5N9MBFzi']          = False     # (N-m/m); ; 
Morison['M6N1MBFzi']          = False     # (N-m/m); ; 
Morison['M6N2MBFzi']          = False     # (N-m/m); ; 
Morison['M6N3MBFzi']          = False     # (N-m/m); ; 
Morison['M6N4MBFzi']          = False     # (N-m/m); ; 
Morison['M6N5MBFzi']          = False     # (N-m/m); ; 
Morison['M6N6MBFzi']          = False     # (N-m/m); ; 
Morison['M6N7MBFzi']          = False     # (N-m/m); ; 
Morison['M6N8MBFzi']          = False     # (N-m/m); ; 
Morison['M6N9MBFzi']          = False     # (N-m/m); ; 
Morison['M7N1MBFzi']          = False     # (N-m/m); ; 
Morison['M7N2MBFzi']          = False     # (N-m/m); ; 
Morison['M7N3MBFzi']          = False     # (N-m/m); ; 
Morison['M7N4MBFzi']          = False     # (N-m/m); ; 
Morison['M7N5MBFzi']          = False     # (N-m/m); ; 
Morison['M7N6MBFzi']          = False     # (N-m/m); ; 
Morison['M7N7MBFzi']          = False     # (N-m/m); ; 
Morison['M7N8MBFzi']          = False     # (N-m/m); ; 
Morison['M7N9MBFzi']          = False     # (N-m/m); ; 
Morison['M8N1MBFzi']          = False     # (N-m/m); ; 
Morison['M8N2MBFzi']          = False     # (N-m/m); ; 
Morison['M8N3MBFzi']          = False     # (N-m/m); ; 
Morison['M8N4MBFzi']          = False     # (N-m/m); ; 
Morison['M8N5MBFzi']          = False     # (N-m/m); ; 
Morison['M8N6MBFzi']          = False     # (N-m/m); ; 
Morison['M8N7MBFzi']          = False     # (N-m/m); ; 
Morison['M8N8MBFzi']          = False     # (N-m/m); ; 
Morison['M8N9MBFzi']          = False     # (N-m/m); ; 
Morison['M9N1MBFzi']          = False     # (N-m/m); ; 
Morison['M9N2MBFzi']          = False     # (N-m/m); ; 
Morison['M9N3MBFzi']          = False     # (N-m/m); ; 
Morison['M9N4MBFzi']          = False     # (N-m/m); ; 
Morison['M9N5MBFzi']          = False     # (N-m/m); ; 
Morison['M9N6MBFzi']          = False     # (N-m/m); ; 
Morison['M9N7MBFzi']          = False     # (N-m/m); ; 
Morison['M9N8MBFzi']          = False     # (N-m/m); ; 
Morison['M9N9MBFzi']          = False     # (N-m/m); ; 
Morison['M1N1FMGxi']          = False     # (N/m); x-component of the distributed marine growth weight force expressed in the inertial coordinate system; 
Morison['M1N2FMGxi']          = False     # (N/m); ; 
Morison['M1N3FMGxi']          = False     # (N/m); ; 
Morison['M1N4FMGxi']          = False     # (N/m); ; 
Morison['M1N5FMGxi']          = False     # (N/m); ; 
Morison['M1N6FMGxi']          = False     # (N/m); ; 
Morison['M1N7FMGxi']          = False     # (N/m); ; 
Morison['M1N8FMGxi']          = False     # (N/m); ; 
Morison['M1N9FMGxi']          = False     # (N/m); ; 
Morison['M2N1FMGxi']          = False     # (N/m); ; 
Morison['M2N2FMGxi']          = False     # (N/m); ; 
Morison['M2N3FMGxi']          = False     # (N/m); ; 
Morison['M2N4FMGxi']          = False     # (N/m); ; 
Morison['M2N5FMGxi']          = False     # (N/m); ; 
Morison['M2N6FMGxi']          = False     # (N/m); ; 
Morison['M2N7FMGxi']          = False     # (N/m); ; 
Morison['M2N8FMGxi']          = False     # (N/m); ; 
Morison['M2N9FMGxi']          = False     # (N/m); ; 
Morison['M3N1FMGxi']          = False     # (N/m); ; 
Morison['M3N2FMGxi']          = False     # (N/m); ; 
Morison['M3N3FMGxi']          = False     # (N/m); ; 
Morison['M3N4FMGxi']          = False     # (N/m); ; 
Morison['M3N5FMGxi']          = False     # (N/m); ; 
Morison['M3N6FMGxi']          = False     # (N/m); ; 
Morison['M3N7FMGxi']          = False     # (N/m); ; 
Morison['M3N8FMGxi']          = False     # (N/m); ; 
Morison['M3N9FMGxi']          = False     # (N/m); ; 
Morison['M4N1FMGxi']          = False     # (N/m); ; 
Morison['M4N2FMGxi']          = False     # (N/m); ; 
Morison['M4N3FMGxi']          = False     # (N/m); ; 
Morison['M4N4FMGxi']          = False     # (N/m); ; 
Morison['M4N5FMGxi']          = False     # (N/m); ; 
Morison['M4N6FMGxi']          = False     # (N/m); ; 
Morison['M4N7FMGxi']          = False     # (N/m); ; 
Morison['M4N8FMGxi']          = False     # (N/m); ; 
Morison['M4N9FMGxi']          = False     # (N/m); ; 
Morison['M5N1FMGxi']          = False     # (N/m); ; 
Morison['M5N2FMGxi']          = False     # (N/m); ; 
Morison['M5N3FMGxi']          = False     # (N/m); ; 
Morison['M5N4FMGxi']          = False     # (N/m); ; 
Morison['M5N5FMGxi']          = False     # (N/m); ; 
Morison['M5N6FMGxi']          = False     # (N/m); ; 
Morison['M5N7FMGxi']          = False     # (N/m); ; 
Morison['M5N8FMGxi']          = False     # (N/m); ; 
Morison['M5N9FMGxi']          = False     # (N/m); ; 
Morison['M6N1FMGxi']          = False     # (N/m); ; 
Morison['M6N2FMGxi']          = False     # (N/m); ; 
Morison['M6N3FMGxi']          = False     # (N/m); ; 
Morison['M6N4FMGxi']          = False     # (N/m); ; 
Morison['M6N5FMGxi']          = False     # (N/m); ; 
Morison['M6N6FMGxi']          = False     # (N/m); ; 
Morison['M6N7FMGxi']          = False     # (N/m); ; 
Morison['M6N8FMGxi']          = False     # (N/m); ; 
Morison['M6N9FMGxi']          = False     # (N/m); ; 
Morison['M7N1FMGxi']          = False     # (N/m); ; 
Morison['M7N2FMGxi']          = False     # (N/m); ; 
Morison['M7N3FMGxi']          = False     # (N/m); ; 
Morison['M7N4FMGxi']          = False     # (N/m); ; 
Morison['M7N5FMGxi']          = False     # (N/m); ; 
Morison['M7N6FMGxi']          = False     # (N/m); ; 
Morison['M7N7FMGxi']          = False     # (N/m); ; 
Morison['M7N8FMGxi']          = False     # (N/m); ; 
Morison['M7N9FMGxi']          = False     # (N/m); ; 
Morison['M8N1FMGxi']          = False     # (N/m); ; 
Morison['M8N2FMGxi']          = False     # (N/m); ; 
Morison['M8N3FMGxi']          = False     # (N/m); ; 
Morison['M8N4FMGxi']          = False     # (N/m); ; 
Morison['M8N5FMGxi']          = False     # (N/m); ; 
Morison['M8N6FMGxi']          = False     # (N/m); ; 
Morison['M8N7FMGxi']          = False     # (N/m); ; 
Morison['M8N8FMGxi']          = False     # (N/m); ; 
Morison['M8N9FMGxi']          = False     # (N/m); ; 
Morison['M9N1FMGxi']          = False     # (N/m); ; 
Morison['M9N2FMGxi']          = False     # (N/m); ; 
Morison['M9N3FMGxi']          = False     # (N/m); ; 
Morison['M9N4FMGxi']          = False     # (N/m); ; 
Morison['M9N5FMGxi']          = False     # (N/m); ; 
Morison['M9N6FMGxi']          = False     # (N/m); ; 
Morison['M9N7FMGxi']          = False     # (N/m); ; 
Morison['M9N8FMGxi']          = False     # (N/m); ; 
Morison['M9N9FMGxi']          = False     # (N/m); ; 
Morison['M1N1FMGyi']          = False     # (N/m); y-component of the distributed marine growth weight  force expressed in the inertial coordinate system; 
Morison['M1N2FMGyi']          = False     # (N/m); ; 
Morison['M1N3FMGyi']          = False     # (N/m); ; 
Morison['M1N4FMGyi']          = False     # (N/m); ; 
Morison['M1N5FMGyi']          = False     # (N/m); ; 
Morison['M1N6FMGyi']          = False     # (N/m); ; 
Morison['M1N7FMGyi']          = False     # (N/m); ; 
Morison['M1N8FMGyi']          = False     # (N/m); ; 
Morison['M1N9FMGyi']          = False     # (N/m); ; 
Morison['M2N1FMGyi']          = False     # (N/m); ; 
Morison['M2N2FMGyi']          = False     # (N/m); ; 
Morison['M2N3FMGyi']          = False     # (N/m); ; 
Morison['M2N4FMGyi']          = False     # (N/m); ; 
Morison['M2N5FMGyi']          = False     # (N/m); ; 
Morison['M2N6FMGyi']          = False     # (N/m); ; 
Morison['M2N7FMGyi']          = False     # (N/m); ; 
Morison['M2N8FMGyi']          = False     # (N/m); ; 
Morison['M2N9FMGyi']          = False     # (N/m); ; 
Morison['M3N1FMGyi']          = False     # (N/m); ; 
Morison['M3N2FMGyi']          = False     # (N/m); ; 
Morison['M3N3FMGyi']          = False     # (N/m); ; 
Morison['M3N4FMGyi']          = False     # (N/m); ; 
Morison['M3N5FMGyi']          = False     # (N/m); ; 
Morison['M3N6FMGyi']          = False     # (N/m); ; 
Morison['M3N7FMGyi']          = False     # (N/m); ; 
Morison['M3N8FMGyi']          = False     # (N/m); ; 
Morison['M3N9FMGyi']          = False     # (N/m); ; 
Morison['M4N1FMGyi']          = False     # (N/m); ; 
Morison['M4N2FMGyi']          = False     # (N/m); ; 
Morison['M4N3FMGyi']          = False     # (N/m); ; 
Morison['M4N4FMGyi']          = False     # (N/m); ; 
Morison['M4N5FMGyi']          = False     # (N/m); ; 
Morison['M4N6FMGyi']          = False     # (N/m); ; 
Morison['M4N7FMGyi']          = False     # (N/m); ; 
Morison['M4N8FMGyi']          = False     # (N/m); ; 
Morison['M4N9FMGyi']          = False     # (N/m); ; 
Morison['M5N1FMGyi']          = False     # (N/m); ; 
Morison['M5N2FMGyi']          = False     # (N/m); ; 
Morison['M5N3FMGyi']          = False     # (N/m); ; 
Morison['M5N4FMGyi']          = False     # (N/m); ; 
Morison['M5N5FMGyi']          = False     # (N/m); ; 
Morison['M5N6FMGyi']          = False     # (N/m); ; 
Morison['M5N7FMGyi']          = False     # (N/m); ; 
Morison['M5N8FMGyi']          = False     # (N/m); ; 
Morison['M5N9FMGyi']          = False     # (N/m); ; 
Morison['M6N1FMGyi']          = False     # (N/m); ; 
Morison['M6N2FMGyi']          = False     # (N/m); ; 
Morison['M6N3FMGyi']          = False     # (N/m); ; 
Morison['M6N4FMGyi']          = False     # (N/m); ; 
Morison['M6N5FMGyi']          = False     # (N/m); ; 
Morison['M6N6FMGyi']          = False     # (N/m); ; 
Morison['M6N7FMGyi']          = False     # (N/m); ; 
Morison['M6N8FMGyi']          = False     # (N/m); ; 
Morison['M6N9FMGyi']          = False     # (N/m); ; 
Morison['M7N1FMGyi']          = False     # (N/m); ; 
Morison['M7N2FMGyi']          = False     # (N/m); ; 
Morison['M7N3FMGyi']          = False     # (N/m); ; 
Morison['M7N4FMGyi']          = False     # (N/m); ; 
Morison['M7N5FMGyi']          = False     # (N/m); ; 
Morison['M7N6FMGyi']          = False     # (N/m); ; 
Morison['M7N7FMGyi']          = False     # (N/m); ; 
Morison['M7N8FMGyi']          = False     # (N/m); ; 
Morison['M7N9FMGyi']          = False     # (N/m); ; 
Morison['M8N1FMGyi']          = False     # (N/m); ; 
Morison['M8N2FMGyi']          = False     # (N/m); ; 
Morison['M8N3FMGyi']          = False     # (N/m); ; 
Morison['M8N4FMGyi']          = False     # (N/m); ; 
Morison['M8N5FMGyi']          = False     # (N/m); ; 
Morison['M8N6FMGyi']          = False     # (N/m); ; 
Morison['M8N7FMGyi']          = False     # (N/m); ; 
Morison['M8N8FMGyi']          = False     # (N/m); ; 
Morison['M8N9FMGyi']          = False     # (N/m); ; 
Morison['M9N1FMGyi']          = False     # (N/m); ; 
Morison['M9N2FMGyi']          = False     # (N/m); ; 
Morison['M9N3FMGyi']          = False     # (N/m); ; 
Morison['M9N4FMGyi']          = False     # (N/m); ; 
Morison['M9N5FMGyi']          = False     # (N/m); ; 
Morison['M9N6FMGyi']          = False     # (N/m); ; 
Morison['M9N7FMGyi']          = False     # (N/m); ; 
Morison['M9N8FMGyi']          = False     # (N/m); ; 
Morison['M9N9FMGyi']          = False     # (N/m); ; 
Morison['M1N1FMGzi']          = False     # (N/m); z-component of the distributed marine growth weight force expressed in the inertial coordinate system; 
Morison['M1N2FMGzi']          = False     # (N/m); ; 
Morison['M1N3FMGzi']          = False     # (N/m); ; 
Morison['M1N4FMGzi']          = False     # (N/m); ; 
Morison['M1N5FMGzi']          = False     # (N/m); ; 
Morison['M1N6FMGzi']          = False     # (N/m); ; 
Morison['M1N7FMGzi']          = False     # (N/m); ; 
Morison['M1N8FMGzi']          = False     # (N/m); ; 
Morison['M1N9FMGzi']          = False     # (N/m); ; 
Morison['M2N1FMGzi']          = False     # (N/m); ; 
Morison['M2N2FMGzi']          = False     # (N/m); ; 
Morison['M2N3FMGzi']          = False     # (N/m); ; 
Morison['M2N4FMGzi']          = False     # (N/m); ; 
Morison['M2N5FMGzi']          = False     # (N/m); ; 
Morison['M2N6FMGzi']          = False     # (N/m); ; 
Morison['M2N7FMGzi']          = False     # (N/m); ; 
Morison['M2N8FMGzi']          = False     # (N/m); ; 
Morison['M2N9FMGzi']          = False     # (N/m); ; 
Morison['M3N1FMGzi']          = False     # (N/m); ; 
Morison['M3N2FMGzi']          = False     # (N/m); ; 
Morison['M3N3FMGzi']          = False     # (N/m); ; 
Morison['M3N4FMGzi']          = False     # (N/m); ; 
Morison['M3N5FMGzi']          = False     # (N/m); ; 
Morison['M3N6FMGzi']          = False     # (N/m); ; 
Morison['M3N7FMGzi']          = False     # (N/m); ; 
Morison['M3N8FMGzi']          = False     # (N/m); ; 
Morison['M3N9FMGzi']          = False     # (N/m); ; 
Morison['M4N1FMGzi']          = False     # (N/m); ; 
Morison['M4N2FMGzi']          = False     # (N/m); ; 
Morison['M4N3FMGzi']          = False     # (N/m); ; 
Morison['M4N4FMGzi']          = False     # (N/m); ; 
Morison['M4N5FMGzi']          = False     # (N/m); ; 
Morison['M4N6FMGzi']          = False     # (N/m); ; 
Morison['M4N7FMGzi']          = False     # (N/m); ; 
Morison['M4N8FMGzi']          = False     # (N/m); ; 
Morison['M4N9FMGzi']          = False     # (N/m); ; 
Morison['M5N1FMGzi']          = False     # (N/m); ; 
Morison['M5N2FMGzi']          = False     # (N/m); ; 
Morison['M5N3FMGzi']          = False     # (N/m); ; 
Morison['M5N4FMGzi']          = False     # (N/m); ; 
Morison['M5N5FMGzi']          = False     # (N/m); ; 
Morison['M5N6FMGzi']          = False     # (N/m); ; 
Morison['M5N7FMGzi']          = False     # (N/m); ; 
Morison['M5N8FMGzi']          = False     # (N/m); ; 
Morison['M5N9FMGzi']          = False     # (N/m); ; 
Morison['M6N1FMGzi']          = False     # (N/m); ; 
Morison['M6N2FMGzi']          = False     # (N/m); ; 
Morison['M6N3FMGzi']          = False     # (N/m); ; 
Morison['M6N4FMGzi']          = False     # (N/m); ; 
Morison['M6N5FMGzi']          = False     # (N/m); ; 
Morison['M6N6FMGzi']          = False     # (N/m); ; 
Morison['M6N7FMGzi']          = False     # (N/m); ; 
Morison['M6N8FMGzi']          = False     # (N/m); ; 
Morison['M6N9FMGzi']          = False     # (N/m); ; 
Morison['M7N1FMGzi']          = False     # (N/m); ; 
Morison['M7N2FMGzi']          = False     # (N/m); ; 
Morison['M7N3FMGzi']          = False     # (N/m); ; 
Morison['M7N4FMGzi']          = False     # (N/m); ; 
Morison['M7N5FMGzi']          = False     # (N/m); ; 
Morison['M7N6FMGzi']          = False     # (N/m); ; 
Morison['M7N7FMGzi']          = False     # (N/m); ; 
Morison['M7N8FMGzi']          = False     # (N/m); ; 
Morison['M7N9FMGzi']          = False     # (N/m); ; 
Morison['M8N1FMGzi']          = False     # (N/m); ; 
Morison['M8N2FMGzi']          = False     # (N/m); ; 
Morison['M8N3FMGzi']          = False     # (N/m); ; 
Morison['M8N4FMGzi']          = False     # (N/m); ; 
Morison['M8N5FMGzi']          = False     # (N/m); ; 
Morison['M8N6FMGzi']          = False     # (N/m); ; 
Morison['M8N7FMGzi']          = False     # (N/m); ; 
Morison['M8N8FMGzi']          = False     # (N/m); ; 
Morison['M8N9FMGzi']          = False     # (N/m); ; 
Morison['M9N1FMGzi']          = False     # (N/m); ; 
Morison['M9N2FMGzi']          = False     # (N/m); ; 
Morison['M9N3FMGzi']          = False     # (N/m); ; 
Morison['M9N4FMGzi']          = False     # (N/m); ; 
Morison['M9N5FMGzi']          = False     # (N/m); ; 
Morison['M9N6FMGzi']          = False     # (N/m); ; 
Morison['M9N7FMGzi']          = False     # (N/m); ; 
Morison['M9N8FMGzi']          = False     # (N/m); ; 
Morison['M9N9FMGzi']          = False     # (N/m); ; 
Morison['M1N1MMGxi']          = False     # (N-m/m); x-component of the distributed marine growth weight moment expressed in the inertial coordinate system; 
Morison['M1N2MMGxi']          = False     # (N-m/m); ; 
Morison['M1N3MMGxi']          = False     # (N-m/m); ; 
Morison['M1N4MMGxi']          = False     # (N-m/m); ; 
Morison['M1N5MMGxi']          = False     # (N-m/m); ; 
Morison['M1N6MMGxi']          = False     # (N-m/m); ; 
Morison['M1N7MMGxi']          = False     # (N-m/m); ; 
Morison['M1N8MMGxi']          = False     # (N-m/m); ; 
Morison['M1N9MMGxi']          = False     # (N-m/m); ; 
Morison['M2N1MMGxi']          = False     # (N-m/m); ; 
Morison['M2N2MMGxi']          = False     # (N-m/m); ; 
Morison['M2N3MMGxi']          = False     # (N-m/m); ; 
Morison['M2N4MMGxi']          = False     # (N-m/m); ; 
Morison['M2N5MMGxi']          = False     # (N-m/m); ; 
Morison['M2N6MMGxi']          = False     # (N-m/m); ; 
Morison['M2N7MMGxi']          = False     # (N-m/m); ; 
Morison['M2N8MMGxi']          = False     # (N-m/m); ; 
Morison['M2N9MMGxi']          = False     # (N-m/m); ; 
Morison['M3N1MMGxi']          = False     # (N-m/m); ; 
Morison['M3N2MMGxi']          = False     # (N-m/m); ; 
Morison['M3N3MMGxi']          = False     # (N-m/m); ; 
Morison['M3N4MMGxi']          = False     # (N-m/m); ; 
Morison['M3N5MMGxi']          = False     # (N-m/m); ; 
Morison['M3N6MMGxi']          = False     # (N-m/m); ; 
Morison['M3N7MMGxi']          = False     # (N-m/m); ; 
Morison['M3N8MMGxi']          = False     # (N-m/m); ; 
Morison['M3N9MMGxi']          = False     # (N-m/m); ; 
Morison['M4N1MMGxi']          = False     # (N-m/m); ; 
Morison['M4N2MMGxi']          = False     # (N-m/m); ; 
Morison['M4N3MMGxi']          = False     # (N-m/m); ; 
Morison['M4N4MMGxi']          = False     # (N-m/m); ; 
Morison['M4N5MMGxi']          = False     # (N-m/m); ; 
Morison['M4N6MMGxi']          = False     # (N-m/m); ; 
Morison['M4N7MMGxi']          = False     # (N-m/m); ; 
Morison['M4N8MMGxi']          = False     # (N-m/m); ; 
Morison['M4N9MMGxi']          = False     # (N-m/m); ; 
Morison['M5N1MMGxi']          = False     # (N-m/m); ; 
Morison['M5N2MMGxi']          = False     # (N-m/m); ; 
Morison['M5N3MMGxi']          = False     # (N-m/m); ; 
Morison['M5N4MMGxi']          = False     # (N-m/m); ; 
Morison['M5N5MMGxi']          = False     # (N-m/m); ; 
Morison['M5N6MMGxi']          = False     # (N-m/m); ; 
Morison['M5N7MMGxi']          = False     # (N-m/m); ; 
Morison['M5N8MMGxi']          = False     # (N-m/m); ; 
Morison['M5N9MMGxi']          = False     # (N-m/m); ; 
Morison['M6N1MMGxi']          = False     # (N-m/m); ; 
Morison['M6N2MMGxi']          = False     # (N-m/m); ; 
Morison['M6N3MMGxi']          = False     # (N-m/m); ; 
Morison['M6N4MMGxi']          = False     # (N-m/m); ; 
Morison['M6N5MMGxi']          = False     # (N-m/m); ; 
Morison['M6N6MMGxi']          = False     # (N-m/m); ; 
Morison['M6N7MMGxi']          = False     # (N-m/m); ; 
Morison['M6N8MMGxi']          = False     # (N-m/m); ; 
Morison['M6N9MMGxi']          = False     # (N-m/m); ; 
Morison['M7N1MMGxi']          = False     # (N-m/m); ; 
Morison['M7N2MMGxi']          = False     # (N-m/m); ; 
Morison['M7N3MMGxi']          = False     # (N-m/m); ; 
Morison['M7N4MMGxi']          = False     # (N-m/m); ; 
Morison['M7N5MMGxi']          = False     # (N-m/m); ; 
Morison['M7N6MMGxi']          = False     # (N-m/m); ; 
Morison['M7N7MMGxi']          = False     # (N-m/m); ; 
Morison['M7N8MMGxi']          = False     # (N-m/m); ; 
Morison['M7N9MMGxi']          = False     # (N-m/m); ; 
Morison['M8N1MMGxi']          = False     # (N-m/m); ; 
Morison['M8N2MMGxi']          = False     # (N-m/m); ; 
Morison['M8N3MMGxi']          = False     # (N-m/m); ; 
Morison['M8N4MMGxi']          = False     # (N-m/m); ; 
Morison['M8N5MMGxi']          = False     # (N-m/m); ; 
Morison['M8N6MMGxi']          = False     # (N-m/m); ; 
Morison['M8N7MMGxi']          = False     # (N-m/m); ; 
Morison['M8N8MMGxi']          = False     # (N-m/m); ; 
Morison['M8N9MMGxi']          = False     # (N-m/m); ; 
Morison['M9N1MMGxi']          = False     # (N-m/m); ; 
Morison['M9N2MMGxi']          = False     # (N-m/m); ; 
Morison['M9N3MMGxi']          = False     # (N-m/m); ; 
Morison['M9N4MMGxi']          = False     # (N-m/m); ; 
Morison['M9N5MMGxi']          = False     # (N-m/m); ; 
Morison['M9N6MMGxi']          = False     # (N-m/m); ; 
Morison['M9N7MMGxi']          = False     # (N-m/m); ; 
Morison['M9N8MMGxi']          = False     # (N-m/m); ; 
Morison['M9N9MMGxi']          = False     # (N-m/m); ; 
Morison['M1N1MMGyi']          = False     # (N-m/m); y-component of the distributed marine growth weight  moment expressed in the inertial coordinate system; 
Morison['M1N2MMGyi']          = False     # (N-m/m); ; 
Morison['M1N3MMGyi']          = False     # (N-m/m); ; 
Morison['M1N4MMGyi']          = False     # (N-m/m); ; 
Morison['M1N5MMGyi']          = False     # (N-m/m); ; 
Morison['M1N6MMGyi']          = False     # (N-m/m); ; 
Morison['M1N7MMGyi']          = False     # (N-m/m); ; 
Morison['M1N8MMGyi']          = False     # (N-m/m); ; 
Morison['M1N9MMGyi']          = False     # (N-m/m); ; 
Morison['M2N1MMGyi']          = False     # (N-m/m); ; 
Morison['M2N2MMGyi']          = False     # (N-m/m); ; 
Morison['M2N3MMGyi']          = False     # (N-m/m); ; 
Morison['M2N4MMGyi']          = False     # (N-m/m); ; 
Morison['M2N5MMGyi']          = False     # (N-m/m); ; 
Morison['M2N6MMGyi']          = False     # (N-m/m); ; 
Morison['M2N7MMGyi']          = False     # (N-m/m); ; 
Morison['M2N8MMGyi']          = False     # (N-m/m); ; 
Morison['M2N9MMGyi']          = False     # (N-m/m); ; 
Morison['M3N1MMGyi']          = False     # (N-m/m); ; 
Morison['M3N2MMGyi']          = False     # (N-m/m); ; 
Morison['M3N3MMGyi']          = False     # (N-m/m); ; 
Morison['M3N4MMGyi']          = False     # (N-m/m); ; 
Morison['M3N5MMGyi']          = False     # (N-m/m); ; 
Morison['M3N6MMGyi']          = False     # (N-m/m); ; 
Morison['M3N7MMGyi']          = False     # (N-m/m); ; 
Morison['M3N8MMGyi']          = False     # (N-m/m); ; 
Morison['M3N9MMGyi']          = False     # (N-m/m); ; 
Morison['M4N1MMGyi']          = False     # (N-m/m); ; 
Morison['M4N2MMGyi']          = False     # (N-m/m); ; 
Morison['M4N3MMGyi']          = False     # (N-m/m); ; 
Morison['M4N4MMGyi']          = False     # (N-m/m); ; 
Morison['M4N5MMGyi']          = False     # (N-m/m); ; 
Morison['M4N6MMGyi']          = False     # (N-m/m); ; 
Morison['M4N7MMGyi']          = False     # (N-m/m); ; 
Morison['M4N8MMGyi']          = False     # (N-m/m); ; 
Morison['M4N9MMGyi']          = False     # (N-m/m); ; 
Morison['M5N1MMGyi']          = False     # (N-m/m); ; 
Morison['M5N2MMGyi']          = False     # (N-m/m); ; 
Morison['M5N3MMGyi']          = False     # (N-m/m); ; 
Morison['M5N4MMGyi']          = False     # (N-m/m); ; 
Morison['M5N5MMGyi']          = False     # (N-m/m); ; 
Morison['M5N6MMGyi']          = False     # (N-m/m); ; 
Morison['M5N7MMGyi']          = False     # (N-m/m); ; 
Morison['M5N8MMGyi']          = False     # (N-m/m); ; 
Morison['M5N9MMGyi']          = False     # (N-m/m); ; 
Morison['M6N1MMGyi']          = False     # (N-m/m); ; 
Morison['M6N2MMGyi']          = False     # (N-m/m); ; 
Morison['M6N3MMGyi']          = False     # (N-m/m); ; 
Morison['M6N4MMGyi']          = False     # (N-m/m); ; 
Morison['M6N5MMGyi']          = False     # (N-m/m); ; 
Morison['M6N6MMGyi']          = False     # (N-m/m); ; 
Morison['M6N7MMGyi']          = False     # (N-m/m); ; 
Morison['M6N8MMGyi']          = False     # (N-m/m); ; 
Morison['M6N9MMGyi']          = False     # (N-m/m); ; 
Morison['M7N1MMGyi']          = False     # (N-m/m); ; 
Morison['M7N2MMGyi']          = False     # (N-m/m); ; 
Morison['M7N3MMGyi']          = False     # (N-m/m); ; 
Morison['M7N4MMGyi']          = False     # (N-m/m); ; 
Morison['M7N5MMGyi']          = False     # (N-m/m); ; 
Morison['M7N6MMGyi']          = False     # (N-m/m); ; 
Morison['M7N7MMGyi']          = False     # (N-m/m); ; 
Morison['M7N8MMGyi']          = False     # (N-m/m); ; 
Morison['M7N9MMGyi']          = False     # (N-m/m); ; 
Morison['M8N1MMGyi']          = False     # (N-m/m); ; 
Morison['M8N2MMGyi']          = False     # (N-m/m); ; 
Morison['M8N3MMGyi']          = False     # (N-m/m); ; 
Morison['M8N4MMGyi']          = False     # (N-m/m); ; 
Morison['M8N5MMGyi']          = False     # (N-m/m); ; 
Morison['M8N6MMGyi']          = False     # (N-m/m); ; 
Morison['M8N7MMGyi']          = False     # (N-m/m); ; 
Morison['M8N8MMGyi']          = False     # (N-m/m); ; 
Morison['M8N9MMGyi']          = False     # (N-m/m); ; 
Morison['M9N1MMGyi']          = False     # (N-m/m); ; 
Morison['M9N2MMGyi']          = False     # (N-m/m); ; 
Morison['M9N3MMGyi']          = False     # (N-m/m); ; 
Morison['M9N4MMGyi']          = False     # (N-m/m); ; 
Morison['M9N5MMGyi']          = False     # (N-m/m); ; 
Morison['M9N6MMGyi']          = False     # (N-m/m); ; 
Morison['M9N7MMGyi']          = False     # (N-m/m); ; 
Morison['M9N8MMGyi']          = False     # (N-m/m); ; 
Morison['M9N9MMGyi']          = False     # (N-m/m); ; 
Morison['M1N1MMGzi']          = False     # (N-m/m); z-component of the distributed marine growth weight moment expressed in the inertial coordinate system; 
Morison['M1N2MMGzi']          = False     # (N-m/m); ; 
Morison['M1N3MMGzi']          = False     # (N-m/m); ; 
Morison['M1N4MMGzi']          = False     # (N-m/m); ; 
Morison['M1N5MMGzi']          = False     # (N-m/m); ; 
Morison['M1N6MMGzi']          = False     # (N-m/m); ; 
Morison['M1N7MMGzi']          = False     # (N-m/m); ; 
Morison['M1N8MMGzi']          = False     # (N-m/m); ; 
Morison['M1N9MMGzi']          = False     # (N-m/m); ; 
Morison['M2N1MMGzi']          = False     # (N-m/m); ; 
Morison['M2N2MMGzi']          = False     # (N-m/m); ; 
Morison['M2N3MMGzi']          = False     # (N-m/m); ; 
Morison['M2N4MMGzi']          = False     # (N-m/m); ; 
Morison['M2N5MMGzi']          = False     # (N-m/m); ; 
Morison['M2N6MMGzi']          = False     # (N-m/m); ; 
Morison['M2N7MMGzi']          = False     # (N-m/m); ; 
Morison['M2N8MMGzi']          = False     # (N-m/m); ; 
Morison['M2N9MMGzi']          = False     # (N-m/m); ; 
Morison['M3N1MMGzi']          = False     # (N-m/m); ; 
Morison['M3N2MMGzi']          = False     # (N-m/m); ; 
Morison['M3N3MMGzi']          = False     # (N-m/m); ; 
Morison['M3N4MMGzi']          = False     # (N-m/m); ; 
Morison['M3N5MMGzi']          = False     # (N-m/m); ; 
Morison['M3N6MMGzi']          = False     # (N-m/m); ; 
Morison['M3N7MMGzi']          = False     # (N-m/m); ; 
Morison['M3N8MMGzi']          = False     # (N-m/m); ; 
Morison['M3N9MMGzi']          = False     # (N-m/m); ; 
Morison['M4N1MMGzi']          = False     # (N-m/m); ; 
Morison['M4N2MMGzi']          = False     # (N-m/m); ; 
Morison['M4N3MMGzi']          = False     # (N-m/m); ; 
Morison['M4N4MMGzi']          = False     # (N-m/m); ; 
Morison['M4N5MMGzi']          = False     # (N-m/m); ; 
Morison['M4N6MMGzi']          = False     # (N-m/m); ; 
Morison['M4N7MMGzi']          = False     # (N-m/m); ; 
Morison['M4N8MMGzi']          = False     # (N-m/m); ; 
Morison['M4N9MMGzi']          = False     # (N-m/m); ; 
Morison['M5N1MMGzi']          = False     # (N-m/m); ; 
Morison['M5N2MMGzi']          = False     # (N-m/m); ; 
Morison['M5N3MMGzi']          = False     # (N-m/m); ; 
Morison['M5N4MMGzi']          = False     # (N-m/m); ; 
Morison['M5N5MMGzi']          = False     # (N-m/m); ; 
Morison['M5N6MMGzi']          = False     # (N-m/m); ; 
Morison['M5N7MMGzi']          = False     # (N-m/m); ; 
Morison['M5N8MMGzi']          = False     # (N-m/m); ; 
Morison['M5N9MMGzi']          = False     # (N-m/m); ; 
Morison['M6N1MMGzi']          = False     # (N-m/m); ; 
Morison['M6N2MMGzi']          = False     # (N-m/m); ; 
Morison['M6N3MMGzi']          = False     # (N-m/m); ; 
Morison['M6N4MMGzi']          = False     # (N-m/m); ; 
Morison['M6N5MMGzi']          = False     # (N-m/m); ; 
Morison['M6N6MMGzi']          = False     # (N-m/m); ; 
Morison['M6N7MMGzi']          = False     # (N-m/m); ; 
Morison['M6N8MMGzi']          = False     # (N-m/m); ; 
Morison['M6N9MMGzi']          = False     # (N-m/m); ; 
Morison['M7N1MMGzi']          = False     # (N-m/m); ; 
Morison['M7N2MMGzi']          = False     # (N-m/m); ; 
Morison['M7N3MMGzi']          = False     # (N-m/m); ; 
Morison['M7N4MMGzi']          = False     # (N-m/m); ; 
Morison['M7N5MMGzi']          = False     # (N-m/m); ; 
Morison['M7N6MMGzi']          = False     # (N-m/m); ; 
Morison['M7N7MMGzi']          = False     # (N-m/m); ; 
Morison['M7N8MMGzi']          = False     # (N-m/m); ; 
Morison['M7N9MMGzi']          = False     # (N-m/m); ; 
Morison['M8N1MMGzi']          = False     # (N-m/m); ; 
Morison['M8N2MMGzi']          = False     # (N-m/m); ; 
Morison['M8N3MMGzi']          = False     # (N-m/m); ; 
Morison['M8N4MMGzi']          = False     # (N-m/m); ; 
Morison['M8N5MMGzi']          = False     # (N-m/m); ; 
Morison['M8N6MMGzi']          = False     # (N-m/m); ; 
Morison['M8N7MMGzi']          = False     # (N-m/m); ; 
Morison['M8N8MMGzi']          = False     # (N-m/m); ; 
Morison['M8N9MMGzi']          = False     # (N-m/m); ; 
Morison['M9N1MMGzi']          = False     # (N-m/m); ; 
Morison['M9N2MMGzi']          = False     # (N-m/m); ; 
Morison['M9N3MMGzi']          = False     # (N-m/m); ; 
Morison['M9N4MMGzi']          = False     # (N-m/m); ; 
Morison['M9N5MMGzi']          = False     # (N-m/m); ; 
Morison['M9N6MMGzi']          = False     # (N-m/m); ; 
Morison['M9N7MMGzi']          = False     # (N-m/m); ; 
Morison['M9N8MMGzi']          = False     # (N-m/m); ; 
Morison['M9N9MMGzi']          = False     # (N-m/m); ; 
Morison['M1N1FAMxi']          = False     # (N/m); x-component of the distributed added mass force due to the member's displacement of the external fluid, expressed in the inertial coordinate system; 
Morison['M1N2FAMxi']          = False     # (N/m); ; 
Morison['M1N3FAMxi']          = False     # (N/m); ; 
Morison['M1N4FAMxi']          = False     # (N/m); ; 
Morison['M1N5FAMxi']          = False     # (N/m); ; 
Morison['M1N6FAMxi']          = False     # (N/m); ; 
Morison['M1N7FAMxi']          = False     # (N/m); ; 
Morison['M1N8FAMxi']          = False     # (N/m); ; 
Morison['M1N9FAMxi']          = False     # (N/m); ; 
Morison['M2N1FAMxi']          = False     # (N/m); ; 
Morison['M2N2FAMxi']          = False     # (N/m); ; 
Morison['M2N3FAMxi']          = False     # (N/m); ; 
Morison['M2N4FAMxi']          = False     # (N/m); ; 
Morison['M2N5FAMxi']          = False     # (N/m); ; 
Morison['M2N6FAMxi']          = False     # (N/m); ; 
Morison['M2N7FAMxi']          = False     # (N/m); ; 
Morison['M2N8FAMxi']          = False     # (N/m); ; 
Morison['M2N9FAMxi']          = False     # (N/m); ; 
Morison['M3N1FAMxi']          = False     # (N/m); ; 
Morison['M3N2FAMxi']          = False     # (N/m); ; 
Morison['M3N3FAMxi']          = False     # (N/m); ; 
Morison['M3N4FAMxi']          = False     # (N/m); ; 
Morison['M3N5FAMxi']          = False     # (N/m); ; 
Morison['M3N6FAMxi']          = False     # (N/m); ; 
Morison['M3N7FAMxi']          = False     # (N/m); ; 
Morison['M3N8FAMxi']          = False     # (N/m); ; 
Morison['M3N9FAMxi']          = False     # (N/m); ; 
Morison['M4N1FAMxi']          = False     # (N/m); ; 
Morison['M4N2FAMxi']          = False     # (N/m); ; 
Morison['M4N3FAMxi']          = False     # (N/m); ; 
Morison['M4N4FAMxi']          = False     # (N/m); ; 
Morison['M4N5FAMxi']          = False     # (N/m); ; 
Morison['M4N6FAMxi']          = False     # (N/m); ; 
Morison['M4N7FAMxi']          = False     # (N/m); ; 
Morison['M4N8FAMxi']          = False     # (N/m); ; 
Morison['M4N9FAMxi']          = False     # (N/m); ; 
Morison['M5N1FAMxi']          = False     # (N/m); ; 
Morison['M5N2FAMxi']          = False     # (N/m); ; 
Morison['M5N3FAMxi']          = False     # (N/m); ; 
Morison['M5N4FAMxi']          = False     # (N/m); ; 
Morison['M5N5FAMxi']          = False     # (N/m); ; 
Morison['M5N6FAMxi']          = False     # (N/m); ; 
Morison['M5N7FAMxi']          = False     # (N/m); ; 
Morison['M5N8FAMxi']          = False     # (N/m); ; 
Morison['M5N9FAMxi']          = False     # (N/m); ; 
Morison['M6N1FAMxi']          = False     # (N/m); ; 
Morison['M6N2FAMxi']          = False     # (N/m); ; 
Morison['M6N3FAMxi']          = False     # (N/m); ; 
Morison['M6N4FAMxi']          = False     # (N/m); ; 
Morison['M6N5FAMxi']          = False     # (N/m); ; 
Morison['M6N6FAMxi']          = False     # (N/m); ; 
Morison['M6N7FAMxi']          = False     # (N/m); ; 
Morison['M6N8FAMxi']          = False     # (N/m); ; 
Morison['M6N9FAMxi']          = False     # (N/m); ; 
Morison['M7N1FAMxi']          = False     # (N/m); ; 
Morison['M7N2FAMxi']          = False     # (N/m); ; 
Morison['M7N3FAMxi']          = False     # (N/m); ; 
Morison['M7N4FAMxi']          = False     # (N/m); ; 
Morison['M7N5FAMxi']          = False     # (N/m); ; 
Morison['M7N6FAMxi']          = False     # (N/m); ; 
Morison['M7N7FAMxi']          = False     # (N/m); ; 
Morison['M7N8FAMxi']          = False     # (N/m); ; 
Morison['M7N9FAMxi']          = False     # (N/m); ; 
Morison['M8N1FAMxi']          = False     # (N/m); ; 
Morison['M8N2FAMxi']          = False     # (N/m); ; 
Morison['M8N3FAMxi']          = False     # (N/m); ; 
Morison['M8N4FAMxi']          = False     # (N/m); ; 
Morison['M8N5FAMxi']          = False     # (N/m); ; 
Morison['M8N6FAMxi']          = False     # (N/m); ; 
Morison['M8N7FAMxi']          = False     # (N/m); ; 
Morison['M8N8FAMxi']          = False     # (N/m); ; 
Morison['M8N9FAMxi']          = False     # (N/m); ; 
Morison['M9N1FAMxi']          = False     # (N/m); ; 
Morison['M9N2FAMxi']          = False     # (N/m); ; 
Morison['M9N3FAMxi']          = False     # (N/m); ; 
Morison['M9N4FAMxi']          = False     # (N/m); ; 
Morison['M9N5FAMxi']          = False     # (N/m); ; 
Morison['M9N6FAMxi']          = False     # (N/m); ; 
Morison['M9N7FAMxi']          = False     # (N/m); ; 
Morison['M9N8FAMxi']          = False     # (N/m); ; 
Morison['M9N9FAMxi']          = False     # (N/m); ; 
Morison['M1N1FAMyi']          = False     # (N/m); y-component of the distributed added mass force due to the member's displacement of the external fluid, expressed in the inertial coordinate system; 
Morison['M1N2FAMyi']          = False     # (N/m); ; 
Morison['M1N3FAMyi']          = False     # (N/m); ; 
Morison['M1N4FAMyi']          = False     # (N/m); ; 
Morison['M1N5FAMyi']          = False     # (N/m); ; 
Morison['M1N6FAMyi']          = False     # (N/m); ; 
Morison['M1N7FAMyi']          = False     # (N/m); ; 
Morison['M1N8FAMyi']          = False     # (N/m); ; 
Morison['M1N9FAMyi']          = False     # (N/m); ; 
Morison['M2N1FAMyi']          = False     # (N/m); ; 
Morison['M2N2FAMyi']          = False     # (N/m); ; 
Morison['M2N3FAMyi']          = False     # (N/m); ; 
Morison['M2N4FAMyi']          = False     # (N/m); ; 
Morison['M2N5FAMyi']          = False     # (N/m); ; 
Morison['M2N6FAMyi']          = False     # (N/m); ; 
Morison['M2N7FAMyi']          = False     # (N/m); ; 
Morison['M2N8FAMyi']          = False     # (N/m); ; 
Morison['M2N9FAMyi']          = False     # (N/m); ; 
Morison['M3N1FAMyi']          = False     # (N/m); ; 
Morison['M3N2FAMyi']          = False     # (N/m); ; 
Morison['M3N3FAMyi']          = False     # (N/m); ; 
Morison['M3N4FAMyi']          = False     # (N/m); ; 
Morison['M3N5FAMyi']          = False     # (N/m); ; 
Morison['M3N6FAMyi']          = False     # (N/m); ; 
Morison['M3N7FAMyi']          = False     # (N/m); ; 
Morison['M3N8FAMyi']          = False     # (N/m); ; 
Morison['M3N9FAMyi']          = False     # (N/m); ; 
Morison['M4N1FAMyi']          = False     # (N/m); ; 
Morison['M4N2FAMyi']          = False     # (N/m); ; 
Morison['M4N3FAMyi']          = False     # (N/m); ; 
Morison['M4N4FAMyi']          = False     # (N/m); ; 
Morison['M4N5FAMyi']          = False     # (N/m); ; 
Morison['M4N6FAMyi']          = False     # (N/m); ; 
Morison['M4N7FAMyi']          = False     # (N/m); ; 
Morison['M4N8FAMyi']          = False     # (N/m); ; 
Morison['M4N9FAMyi']          = False     # (N/m); ; 
Morison['M5N1FAMyi']          = False     # (N/m); ; 
Morison['M5N2FAMyi']          = False     # (N/m); ; 
Morison['M5N3FAMyi']          = False     # (N/m); ; 
Morison['M5N4FAMyi']          = False     # (N/m); ; 
Morison['M5N5FAMyi']          = False     # (N/m); ; 
Morison['M5N6FAMyi']          = False     # (N/m); ; 
Morison['M5N7FAMyi']          = False     # (N/m); ; 
Morison['M5N8FAMyi']          = False     # (N/m); ; 
Morison['M5N9FAMyi']          = False     # (N/m); ; 
Morison['M6N1FAMyi']          = False     # (N/m); ; 
Morison['M6N2FAMyi']          = False     # (N/m); ; 
Morison['M6N3FAMyi']          = False     # (N/m); ; 
Morison['M6N4FAMyi']          = False     # (N/m); ; 
Morison['M6N5FAMyi']          = False     # (N/m); ; 
Morison['M6N6FAMyi']          = False     # (N/m); ; 
Morison['M6N7FAMyi']          = False     # (N/m); ; 
Morison['M6N8FAMyi']          = False     # (N/m); ; 
Morison['M6N9FAMyi']          = False     # (N/m); ; 
Morison['M7N1FAMyi']          = False     # (N/m); ; 
Morison['M7N2FAMyi']          = False     # (N/m); ; 
Morison['M7N3FAMyi']          = False     # (N/m); ; 
Morison['M7N4FAMyi']          = False     # (N/m); ; 
Morison['M7N5FAMyi']          = False     # (N/m); ; 
Morison['M7N6FAMyi']          = False     # (N/m); ; 
Morison['M7N7FAMyi']          = False     # (N/m); ; 
Morison['M7N8FAMyi']          = False     # (N/m); ; 
Morison['M7N9FAMyi']          = False     # (N/m); ; 
Morison['M8N1FAMyi']          = False     # (N/m); ; 
Morison['M8N2FAMyi']          = False     # (N/m); ; 
Morison['M8N3FAMyi']          = False     # (N/m); ; 
Morison['M8N4FAMyi']          = False     # (N/m); ; 
Morison['M8N5FAMyi']          = False     # (N/m); ; 
Morison['M8N6FAMyi']          = False     # (N/m); ; 
Morison['M8N7FAMyi']          = False     # (N/m); ; 
Morison['M8N8FAMyi']          = False     # (N/m); ; 
Morison['M8N9FAMyi']          = False     # (N/m); ; 
Morison['M9N1FAMyi']          = False     # (N/m); ; 
Morison['M9N2FAMyi']          = False     # (N/m); ; 
Morison['M9N3FAMyi']          = False     # (N/m); ; 
Morison['M9N4FAMyi']          = False     # (N/m); ; 
Morison['M9N5FAMyi']          = False     # (N/m); ; 
Morison['M9N6FAMyi']          = False     # (N/m); ; 
Morison['M9N7FAMyi']          = False     # (N/m); ; 
Morison['M9N8FAMyi']          = False     # (N/m); ; 
Morison['M9N9FAMyi']          = False     # (N/m); ; 
Morison['M1N1FAMzi']          = False     # (N/m); z-component of the distributed added mass force due to the member's displacement of the external fluid, expressed in the inertial coordinate system; 
Morison['M1N2FAMzi']          = False     # (N/m); ; 
Morison['M1N3FAMzi']          = False     # (N/m); ; 
Morison['M1N4FAMzi']          = False     # (N/m); ; 
Morison['M1N5FAMzi']          = False     # (N/m); ; 
Morison['M1N6FAMzi']          = False     # (N/m); ; 
Morison['M1N7FAMzi']          = False     # (N/m); ; 
Morison['M1N8FAMzi']          = False     # (N/m); ; 
Morison['M1N9FAMzi']          = False     # (N/m); ; 
Morison['M2N1FAMzi']          = False     # (N/m); ; 
Morison['M2N2FAMzi']          = False     # (N/m); ; 
Morison['M2N3FAMzi']          = False     # (N/m); ; 
Morison['M2N4FAMzi']          = False     # (N/m); ; 
Morison['M2N5FAMzi']          = False     # (N/m); ; 
Morison['M2N6FAMzi']          = False     # (N/m); ; 
Morison['M2N7FAMzi']          = False     # (N/m); ; 
Morison['M2N8FAMzi']          = False     # (N/m); ; 
Morison['M2N9FAMzi']          = False     # (N/m); ; 
Morison['M3N1FAMzi']          = False     # (N/m); ; 
Morison['M3N2FAMzi']          = False     # (N/m); ; 
Morison['M3N3FAMzi']          = False     # (N/m); ; 
Morison['M3N4FAMzi']          = False     # (N/m); ; 
Morison['M3N5FAMzi']          = False     # (N/m); ; 
Morison['M3N6FAMzi']          = False     # (N/m); ; 
Morison['M3N7FAMzi']          = False     # (N/m); ; 
Morison['M3N8FAMzi']          = False     # (N/m); ; 
Morison['M3N9FAMzi']          = False     # (N/m); ; 
Morison['M4N1FAMzi']          = False     # (N/m); ; 
Morison['M4N2FAMzi']          = False     # (N/m); ; 
Morison['M4N3FAMzi']          = False     # (N/m); ; 
Morison['M4N4FAMzi']          = False     # (N/m); ; 
Morison['M4N5FAMzi']          = False     # (N/m); ; 
Morison['M4N6FAMzi']          = False     # (N/m); ; 
Morison['M4N7FAMzi']          = False     # (N/m); ; 
Morison['M4N8FAMzi']          = False     # (N/m); ; 
Morison['M4N9FAMzi']          = False     # (N/m); ; 
Morison['M5N1FAMzi']          = False     # (N/m); ; 
Morison['M5N2FAMzi']          = False     # (N/m); ; 
Morison['M5N3FAMzi']          = False     # (N/m); ; 
Morison['M5N4FAMzi']          = False     # (N/m); ; 
Morison['M5N5FAMzi']          = False     # (N/m); ; 
Morison['M5N6FAMzi']          = False     # (N/m); ; 
Morison['M5N7FAMzi']          = False     # (N/m); ; 
Morison['M5N8FAMzi']          = False     # (N/m); ; 
Morison['M5N9FAMzi']          = False     # (N/m); ; 
Morison['M6N1FAMzi']          = False     # (N/m); ; 
Morison['M6N2FAMzi']          = False     # (N/m); ; 
Morison['M6N3FAMzi']          = False     # (N/m); ; 
Morison['M6N4FAMzi']          = False     # (N/m); ; 
Morison['M6N5FAMzi']          = False     # (N/m); ; 
Morison['M6N6FAMzi']          = False     # (N/m); ; 
Morison['M6N7FAMzi']          = False     # (N/m); ; 
Morison['M6N8FAMzi']          = False     # (N/m); ; 
Morison['M6N9FAMzi']          = False     # (N/m); ; 
Morison['M7N1FAMzi']          = False     # (N/m); ; 
Morison['M7N2FAMzi']          = False     # (N/m); ; 
Morison['M7N3FAMzi']          = False     # (N/m); ; 
Morison['M7N4FAMzi']          = False     # (N/m); ; 
Morison['M7N5FAMzi']          = False     # (N/m); ; 
Morison['M7N6FAMzi']          = False     # (N/m); ; 
Morison['M7N7FAMzi']          = False     # (N/m); ; 
Morison['M7N8FAMzi']          = False     # (N/m); ; 
Morison['M7N9FAMzi']          = False     # (N/m); ; 
Morison['M8N1FAMzi']          = False     # (N/m); ; 
Morison['M8N2FAMzi']          = False     # (N/m); ; 
Morison['M8N3FAMzi']          = False     # (N/m); ; 
Morison['M8N4FAMzi']          = False     # (N/m); ; 
Morison['M8N5FAMzi']          = False     # (N/m); ; 
Morison['M8N6FAMzi']          = False     # (N/m); ; 
Morison['M8N7FAMzi']          = False     # (N/m); ; 
Morison['M8N8FAMzi']          = False     # (N/m); ; 
Morison['M8N9FAMzi']          = False     # (N/m); ; 
Morison['M9N1FAMzi']          = False     # (N/m); ; 
Morison['M9N2FAMzi']          = False     # (N/m); ; 
Morison['M9N3FAMzi']          = False     # (N/m); ; 
Morison['M9N4FAMzi']          = False     # (N/m); ; 
Morison['M9N5FAMzi']          = False     # (N/m); ; 
Morison['M9N6FAMzi']          = False     # (N/m); ; 
Morison['M9N7FAMzi']          = False     # (N/m); ; 
Morison['M9N8FAMzi']          = False     # (N/m); ; 
Morison['M9N9FAMzi']          = False     # (N/m); ; 
Morison['M1N1FAGxi']          = False     # (N/m); x-component of the distributed marine growth mass inertia force, expressed in the inertial coordinate system; 
Morison['M1N2FAGxi']          = False     # (N/m); ; 
Morison['M1N3FAGxi']          = False     # (N/m); ; 
Morison['M1N4FAGxi']          = False     # (N/m); ; 
Morison['M1N5FAGxi']          = False     # (N/m); ; 
Morison['M1N6FAGxi']          = False     # (N/m); ; 
Morison['M1N7FAGxi']          = False     # (N/m); ; 
Morison['M1N8FAGxi']          = False     # (N/m); ; 
Morison['M1N9FAGxi']          = False     # (N/m); ; 
Morison['M2N1FAGxi']          = False     # (N/m); ; 
Morison['M2N2FAGxi']          = False     # (N/m); ; 
Morison['M2N3FAGxi']          = False     # (N/m); ; 
Morison['M2N4FAGxi']          = False     # (N/m); ; 
Morison['M2N5FAGxi']          = False     # (N/m); ; 
Morison['M2N6FAGxi']          = False     # (N/m); ; 
Morison['M2N7FAGxi']          = False     # (N/m); ; 
Morison['M2N8FAGxi']          = False     # (N/m); ; 
Morison['M2N9FAGxi']          = False     # (N/m); ; 
Morison['M3N1FAGxi']          = False     # (N/m); ; 
Morison['M3N2FAGxi']          = False     # (N/m); ; 
Morison['M3N3FAGxi']          = False     # (N/m); ; 
Morison['M3N4FAGxi']          = False     # (N/m); ; 
Morison['M3N5FAGxi']          = False     # (N/m); ; 
Morison['M3N6FAGxi']          = False     # (N/m); ; 
Morison['M3N7FAGxi']          = False     # (N/m); ; 
Morison['M3N8FAGxi']          = False     # (N/m); ; 
Morison['M3N9FAGxi']          = False     # (N/m); ; 
Morison['M4N1FAGxi']          = False     # (N/m); ; 
Morison['M4N2FAGxi']          = False     # (N/m); ; 
Morison['M4N3FAGxi']          = False     # (N/m); ; 
Morison['M4N4FAGxi']          = False     # (N/m); ; 
Morison['M4N5FAGxi']          = False     # (N/m); ; 
Morison['M4N6FAGxi']          = False     # (N/m); ; 
Morison['M4N7FAGxi']          = False     # (N/m); ; 
Morison['M4N8FAGxi']          = False     # (N/m); ; 
Morison['M4N9FAGxi']          = False     # (N/m); ; 
Morison['M5N1FAGxi']          = False     # (N/m); ; 
Morison['M5N2FAGxi']          = False     # (N/m); ; 
Morison['M5N3FAGxi']          = False     # (N/m); ; 
Morison['M5N4FAGxi']          = False     # (N/m); ; 
Morison['M5N5FAGxi']          = False     # (N/m); ; 
Morison['M5N6FAGxi']          = False     # (N/m); ; 
Morison['M5N7FAGxi']          = False     # (N/m); ; 
Morison['M5N8FAGxi']          = False     # (N/m); ; 
Morison['M5N9FAGxi']          = False     # (N/m); ; 
Morison['M6N1FAGxi']          = False     # (N/m); ; 
Morison['M6N2FAGxi']          = False     # (N/m); ; 
Morison['M6N3FAGxi']          = False     # (N/m); ; 
Morison['M6N4FAGxi']          = False     # (N/m); ; 
Morison['M6N5FAGxi']          = False     # (N/m); ; 
Morison['M6N6FAGxi']          = False     # (N/m); ; 
Morison['M6N7FAGxi']          = False     # (N/m); ; 
Morison['M6N8FAGxi']          = False     # (N/m); ; 
Morison['M6N9FAGxi']          = False     # (N/m); ; 
Morison['M7N1FAGxi']          = False     # (N/m); ; 
Morison['M7N2FAGxi']          = False     # (N/m); ; 
Morison['M7N3FAGxi']          = False     # (N/m); ; 
Morison['M7N4FAGxi']          = False     # (N/m); ; 
Morison['M7N5FAGxi']          = False     # (N/m); ; 
Morison['M7N6FAGxi']          = False     # (N/m); ; 
Morison['M7N7FAGxi']          = False     # (N/m); ; 
Morison['M7N8FAGxi']          = False     # (N/m); ; 
Morison['M7N9FAGxi']          = False     # (N/m); ; 
Morison['M8N1FAGxi']          = False     # (N/m); ; 
Morison['M8N2FAGxi']          = False     # (N/m); ; 
Morison['M8N3FAGxi']          = False     # (N/m); ; 
Morison['M8N4FAGxi']          = False     # (N/m); ; 
Morison['M8N5FAGxi']          = False     # (N/m); ; 
Morison['M8N6FAGxi']          = False     # (N/m); ; 
Morison['M8N7FAGxi']          = False     # (N/m); ; 
Morison['M8N8FAGxi']          = False     # (N/m); ; 
Morison['M8N9FAGxi']          = False     # (N/m); ; 
Morison['M9N1FAGxi']          = False     # (N/m); ; 
Morison['M9N2FAGxi']          = False     # (N/m); ; 
Morison['M9N3FAGxi']          = False     # (N/m); ; 
Morison['M9N4FAGxi']          = False     # (N/m); ; 
Morison['M9N5FAGxi']          = False     # (N/m); ; 
Morison['M9N6FAGxi']          = False     # (N/m); ; 
Morison['M9N7FAGxi']          = False     # (N/m); ; 
Morison['M9N8FAGxi']          = False     # (N/m); ; 
Morison['M9N9FAGxi']          = False     # (N/m); ; 
Morison['M1N1FAGyi']          = False     # (N/m); y-component of the distributed marine growth mass inertia force, expressed in the inertial coordinate system; 
Morison['M1N2FAGyi']          = False     # (N/m); ; 
Morison['M1N3FAGyi']          = False     # (N/m); ; 
Morison['M1N4FAGyi']          = False     # (N/m); ; 
Morison['M1N5FAGyi']          = False     # (N/m); ; 
Morison['M1N6FAGyi']          = False     # (N/m); ; 
Morison['M1N7FAGyi']          = False     # (N/m); ; 
Morison['M1N8FAGyi']          = False     # (N/m); ; 
Morison['M1N9FAGyi']          = False     # (N/m); ; 
Morison['M2N1FAGyi']          = False     # (N/m); ; 
Morison['M2N2FAGyi']          = False     # (N/m); ; 
Morison['M2N3FAGyi']          = False     # (N/m); ; 
Morison['M2N4FAGyi']          = False     # (N/m); ; 
Morison['M2N5FAGyi']          = False     # (N/m); ; 
Morison['M2N6FAGyi']          = False     # (N/m); ; 
Morison['M2N7FAGyi']          = False     # (N/m); ; 
Morison['M2N8FAGyi']          = False     # (N/m); ; 
Morison['M2N9FAGyi']          = False     # (N/m); ; 
Morison['M3N1FAGyi']          = False     # (N/m); ; 
Morison['M3N2FAGyi']          = False     # (N/m); ; 
Morison['M3N3FAGyi']          = False     # (N/m); ; 
Morison['M3N4FAGyi']          = False     # (N/m); ; 
Morison['M3N5FAGyi']          = False     # (N/m); ; 
Morison['M3N6FAGyi']          = False     # (N/m); ; 
Morison['M3N7FAGyi']          = False     # (N/m); ; 
Morison['M3N8FAGyi']          = False     # (N/m); ; 
Morison['M3N9FAGyi']          = False     # (N/m); ; 
Morison['M4N1FAGyi']          = False     # (N/m); ; 
Morison['M4N2FAGyi']          = False     # (N/m); ; 
Morison['M4N3FAGyi']          = False     # (N/m); ; 
Morison['M4N4FAGyi']          = False     # (N/m); ; 
Morison['M4N5FAGyi']          = False     # (N/m); ; 
Morison['M4N6FAGyi']          = False     # (N/m); ; 
Morison['M4N7FAGyi']          = False     # (N/m); ; 
Morison['M4N8FAGyi']          = False     # (N/m); ; 
Morison['M4N9FAGyi']          = False     # (N/m); ; 
Morison['M5N1FAGyi']          = False     # (N/m); ; 
Morison['M5N2FAGyi']          = False     # (N/m); ; 
Morison['M5N3FAGyi']          = False     # (N/m); ; 
Morison['M5N4FAGyi']          = False     # (N/m); ; 
Morison['M5N5FAGyi']          = False     # (N/m); ; 
Morison['M5N6FAGyi']          = False     # (N/m); ; 
Morison['M5N7FAGyi']          = False     # (N/m); ; 
Morison['M5N8FAGyi']          = False     # (N/m); ; 
Morison['M5N9FAGyi']          = False     # (N/m); ; 
Morison['M6N1FAGyi']          = False     # (N/m); ; 
Morison['M6N2FAGyi']          = False     # (N/m); ; 
Morison['M6N3FAGyi']          = False     # (N/m); ; 
Morison['M6N4FAGyi']          = False     # (N/m); ; 
Morison['M6N5FAGyi']          = False     # (N/m); ; 
Morison['M6N6FAGyi']          = False     # (N/m); ; 
Morison['M6N7FAGyi']          = False     # (N/m); ; 
Morison['M6N8FAGyi']          = False     # (N/m); ; 
Morison['M6N9FAGyi']          = False     # (N/m); ; 
Morison['M7N1FAGyi']          = False     # (N/m); ; 
Morison['M7N2FAGyi']          = False     # (N/m); ; 
Morison['M7N3FAGyi']          = False     # (N/m); ; 
Morison['M7N4FAGyi']          = False     # (N/m); ; 
Morison['M7N5FAGyi']          = False     # (N/m); ; 
Morison['M7N6FAGyi']          = False     # (N/m); ; 
Morison['M7N7FAGyi']          = False     # (N/m); ; 
Morison['M7N8FAGyi']          = False     # (N/m); ; 
Morison['M7N9FAGyi']          = False     # (N/m); ; 
Morison['M8N1FAGyi']          = False     # (N/m); ; 
Morison['M8N2FAGyi']          = False     # (N/m); ; 
Morison['M8N3FAGyi']          = False     # (N/m); ; 
Morison['M8N4FAGyi']          = False     # (N/m); ; 
Morison['M8N5FAGyi']          = False     # (N/m); ; 
Morison['M8N6FAGyi']          = False     # (N/m); ; 
Morison['M8N7FAGyi']          = False     # (N/m); ; 
Morison['M8N8FAGyi']          = False     # (N/m); ; 
Morison['M8N9FAGyi']          = False     # (N/m); ; 
Morison['M9N1FAGyi']          = False     # (N/m); ; 
Morison['M9N2FAGyi']          = False     # (N/m); ; 
Morison['M9N3FAGyi']          = False     # (N/m); ; 
Morison['M9N4FAGyi']          = False     # (N/m); ; 
Morison['M9N5FAGyi']          = False     # (N/m); ; 
Morison['M9N6FAGyi']          = False     # (N/m); ; 
Morison['M9N7FAGyi']          = False     # (N/m); ; 
Morison['M9N8FAGyi']          = False     # (N/m); ; 
Morison['M9N9FAGyi']          = False     # (N/m); ; 
Morison['M1N1FAGzi']          = False     # (N/m); z-component of the distributed marine growth mass inertia force, expressed in the inertial coordinate system; 
Morison['M1N2FAGzi']          = False     # (N/m); ; 
Morison['M1N3FAGzi']          = False     # (N/m); ; 
Morison['M1N4FAGzi']          = False     # (N/m); ; 
Morison['M1N5FAGzi']          = False     # (N/m); ; 
Morison['M1N6FAGzi']          = False     # (N/m); ; 
Morison['M1N7FAGzi']          = False     # (N/m); ; 
Morison['M1N8FAGzi']          = False     # (N/m); ; 
Morison['M1N9FAGzi']          = False     # (N/m); ; 
Morison['M2N1FAGzi']          = False     # (N/m); ; 
Morison['M2N2FAGzi']          = False     # (N/m); ; 
Morison['M2N3FAGzi']          = False     # (N/m); ; 
Morison['M2N4FAGzi']          = False     # (N/m); ; 
Morison['M2N5FAGzi']          = False     # (N/m); ; 
Morison['M2N6FAGzi']          = False     # (N/m); ; 
Morison['M2N7FAGzi']          = False     # (N/m); ; 
Morison['M2N8FAGzi']          = False     # (N/m); ; 
Morison['M2N9FAGzi']          = False     # (N/m); ; 
Morison['M3N1FAGzi']          = False     # (N/m); ; 
Morison['M3N2FAGzi']          = False     # (N/m); ; 
Morison['M3N3FAGzi']          = False     # (N/m); ; 
Morison['M3N4FAGzi']          = False     # (N/m); ; 
Morison['M3N5FAGzi']          = False     # (N/m); ; 
Morison['M3N6FAGzi']          = False     # (N/m); ; 
Morison['M3N7FAGzi']          = False     # (N/m); ; 
Morison['M3N8FAGzi']          = False     # (N/m); ; 
Morison['M3N9FAGzi']          = False     # (N/m); ; 
Morison['M4N1FAGzi']          = False     # (N/m); ; 
Morison['M4N2FAGzi']          = False     # (N/m); ; 
Morison['M4N3FAGzi']          = False     # (N/m); ; 
Morison['M4N4FAGzi']          = False     # (N/m); ; 
Morison['M4N5FAGzi']          = False     # (N/m); ; 
Morison['M4N6FAGzi']          = False     # (N/m); ; 
Morison['M4N7FAGzi']          = False     # (N/m); ; 
Morison['M4N8FAGzi']          = False     # (N/m); ; 
Morison['M4N9FAGzi']          = False     # (N/m); ; 
Morison['M5N1FAGzi']          = False     # (N/m); ; 
Morison['M5N2FAGzi']          = False     # (N/m); ; 
Morison['M5N3FAGzi']          = False     # (N/m); ; 
Morison['M5N4FAGzi']          = False     # (N/m); ; 
Morison['M5N5FAGzi']          = False     # (N/m); ; 
Morison['M5N6FAGzi']          = False     # (N/m); ; 
Morison['M5N7FAGzi']          = False     # (N/m); ; 
Morison['M5N8FAGzi']          = False     # (N/m); ; 
Morison['M5N9FAGzi']          = False     # (N/m); ; 
Morison['M6N1FAGzi']          = False     # (N/m); ; 
Morison['M6N2FAGzi']          = False     # (N/m); ; 
Morison['M6N3FAGzi']          = False     # (N/m); ; 
Morison['M6N4FAGzi']          = False     # (N/m); ; 
Morison['M6N5FAGzi']          = False     # (N/m); ; 
Morison['M6N6FAGzi']          = False     # (N/m); ; 
Morison['M6N7FAGzi']          = False     # (N/m); ; 
Morison['M6N8FAGzi']          = False     # (N/m); ; 
Morison['M6N9FAGzi']          = False     # (N/m); ; 
Morison['M7N1FAGzi']          = False     # (N/m); ; 
Morison['M7N2FAGzi']          = False     # (N/m); ; 
Morison['M7N3FAGzi']          = False     # (N/m); ; 
Morison['M7N4FAGzi']          = False     # (N/m); ; 
Morison['M7N5FAGzi']          = False     # (N/m); ; 
Morison['M7N6FAGzi']          = False     # (N/m); ; 
Morison['M7N7FAGzi']          = False     # (N/m); ; 
Morison['M7N8FAGzi']          = False     # (N/m); ; 
Morison['M7N9FAGzi']          = False     # (N/m); ; 
Morison['M8N1FAGzi']          = False     # (N/m); ; 
Morison['M8N2FAGzi']          = False     # (N/m); ; 
Morison['M8N3FAGzi']          = False     # (N/m); ; 
Morison['M8N4FAGzi']          = False     # (N/m); ; 
Morison['M8N5FAGzi']          = False     # (N/m); ; 
Morison['M8N6FAGzi']          = False     # (N/m); ; 
Morison['M8N7FAGzi']          = False     # (N/m); ; 
Morison['M8N8FAGzi']          = False     # (N/m); ; 
Morison['M8N9FAGzi']          = False     # (N/m); ; 
Morison['M9N1FAGzi']          = False     # (N/m); ; 
Morison['M9N2FAGzi']          = False     # (N/m); ; 
Morison['M9N3FAGzi']          = False     # (N/m); ; 
Morison['M9N4FAGzi']          = False     # (N/m); ; 
Morison['M9N5FAGzi']          = False     # (N/m); ; 
Morison['M9N6FAGzi']          = False     # (N/m); ; 
Morison['M9N7FAGzi']          = False     # (N/m); ; 
Morison['M9N8FAGzi']          = False     # (N/m); ; 
Morison['M9N9FAGzi']          = False     # (N/m); ; 
Morison['M1N1MAGxi']          = False     # (N-m/m); x-component of the distributed marine growth mass inertia moment, expressed in the inertial coordinate system; 
Morison['M1N2MAGxi']          = False     # (N-m/m); ; 
Morison['M1N3MAGxi']          = False     # (N-m/m); ; 
Morison['M1N4MAGxi']          = False     # (N-m/m); ; 
Morison['M1N5MAGxi']          = False     # (N-m/m); ; 
Morison['M1N6MAGxi']          = False     # (N-m/m); ; 
Morison['M1N7MAGxi']          = False     # (N-m/m); ; 
Morison['M1N8MAGxi']          = False     # (N-m/m); ; 
Morison['M1N9MAGxi']          = False     # (N-m/m); ; 
Morison['M2N1MAGxi']          = False     # (N-m/m); ; 
Morison['M2N2MAGxi']          = False     # (N-m/m); ; 
Morison['M2N3MAGxi']          = False     # (N-m/m); ; 
Morison['M2N4MAGxi']          = False     # (N-m/m); ; 
Morison['M2N5MAGxi']          = False     # (N-m/m); ; 
Morison['M2N6MAGxi']          = False     # (N-m/m); ; 
Morison['M2N7MAGxi']          = False     # (N-m/m); ; 
Morison['M2N8MAGxi']          = False     # (N-m/m); ; 
Morison['M2N9MAGxi']          = False     # (N-m/m); ; 
Morison['M3N1MAGxi']          = False     # (N-m/m); ; 
Morison['M3N2MAGxi']          = False     # (N-m/m); ; 
Morison['M3N3MAGxi']          = False     # (N-m/m); ; 
Morison['M3N4MAGxi']          = False     # (N-m/m); ; 
Morison['M3N5MAGxi']          = False     # (N-m/m); ; 
Morison['M3N6MAGxi']          = False     # (N-m/m); ; 
Morison['M3N7MAGxi']          = False     # (N-m/m); ; 
Morison['M3N8MAGxi']          = False     # (N-m/m); ; 
Morison['M3N9MAGxi']          = False     # (N-m/m); ; 
Morison['M4N1MAGxi']          = False     # (N-m/m); ; 
Morison['M4N2MAGxi']          = False     # (N-m/m); ; 
Morison['M4N3MAGxi']          = False     # (N-m/m); ; 
Morison['M4N4MAGxi']          = False     # (N-m/m); ; 
Morison['M4N5MAGxi']          = False     # (N-m/m); ; 
Morison['M4N6MAGxi']          = False     # (N-m/m); ; 
Morison['M4N7MAGxi']          = False     # (N-m/m); ; 
Morison['M4N8MAGxi']          = False     # (N-m/m); ; 
Morison['M4N9MAGxi']          = False     # (N-m/m); ; 
Morison['M5N1MAGxi']          = False     # (N-m/m); ; 
Morison['M5N2MAGxi']          = False     # (N-m/m); ; 
Morison['M5N3MAGxi']          = False     # (N-m/m); ; 
Morison['M5N4MAGxi']          = False     # (N-m/m); ; 
Morison['M5N5MAGxi']          = False     # (N-m/m); ; 
Morison['M5N6MAGxi']          = False     # (N-m/m); ; 
Morison['M5N7MAGxi']          = False     # (N-m/m); ; 
Morison['M5N8MAGxi']          = False     # (N-m/m); ; 
Morison['M5N9MAGxi']          = False     # (N-m/m); ; 
Morison['M6N1MAGxi']          = False     # (N-m/m); ; 
Morison['M6N2MAGxi']          = False     # (N-m/m); ; 
Morison['M6N3MAGxi']          = False     # (N-m/m); ; 
Morison['M6N4MAGxi']          = False     # (N-m/m); ; 
Morison['M6N5MAGxi']          = False     # (N-m/m); ; 
Morison['M6N6MAGxi']          = False     # (N-m/m); ; 
Morison['M6N7MAGxi']          = False     # (N-m/m); ; 
Morison['M6N8MAGxi']          = False     # (N-m/m); ; 
Morison['M6N9MAGxi']          = False     # (N-m/m); ; 
Morison['M7N1MAGxi']          = False     # (N-m/m); ; 
Morison['M7N2MAGxi']          = False     # (N-m/m); ; 
Morison['M7N3MAGxi']          = False     # (N-m/m); ; 
Morison['M7N4MAGxi']          = False     # (N-m/m); ; 
Morison['M7N5MAGxi']          = False     # (N-m/m); ; 
Morison['M7N6MAGxi']          = False     # (N-m/m); ; 
Morison['M7N7MAGxi']          = False     # (N-m/m); ; 
Morison['M7N8MAGxi']          = False     # (N-m/m); ; 
Morison['M7N9MAGxi']          = False     # (N-m/m); ; 
Morison['M8N1MAGxi']          = False     # (N-m/m); ; 
Morison['M8N2MAGxi']          = False     # (N-m/m); ; 
Morison['M8N3MAGxi']          = False     # (N-m/m); ; 
Morison['M8N4MAGxi']          = False     # (N-m/m); ; 
Morison['M8N5MAGxi']          = False     # (N-m/m); ; 
Morison['M8N6MAGxi']          = False     # (N-m/m); ; 
Morison['M8N7MAGxi']          = False     # (N-m/m); ; 
Morison['M8N8MAGxi']          = False     # (N-m/m); ; 
Morison['M8N9MAGxi']          = False     # (N-m/m); ; 
Morison['M9N1MAGxi']          = False     # (N-m/m); ; 
Morison['M9N2MAGxi']          = False     # (N-m/m); ; 
Morison['M9N3MAGxi']          = False     # (N-m/m); ; 
Morison['M9N4MAGxi']          = False     # (N-m/m); ; 
Morison['M9N5MAGxi']          = False     # (N-m/m); ; 
Morison['M9N6MAGxi']          = False     # (N-m/m); ; 
Morison['M9N7MAGxi']          = False     # (N-m/m); ; 
Morison['M9N8MAGxi']          = False     # (N-m/m); ; 
Morison['M9N9MAGxi']          = False     # (N-m/m); ; 
Morison['M1N1MAGyi']          = False     # (N-m/m); y-component of the distributed marine growth mass inertia moment, expressed in the inertial coordinate system; 
Morison['M1N2MAGyi']          = False     # (N-m/m); ; 
Morison['M1N3MAGyi']          = False     # (N-m/m); ; 
Morison['M1N4MAGyi']          = False     # (N-m/m); ; 
Morison['M1N5MAGyi']          = False     # (N-m/m); ; 
Morison['M1N6MAGyi']          = False     # (N-m/m); ; 
Morison['M1N7MAGyi']          = False     # (N-m/m); ; 
Morison['M1N8MAGyi']          = False     # (N-m/m); ; 
Morison['M1N9MAGyi']          = False     # (N-m/m); ; 
Morison['M2N1MAGyi']          = False     # (N-m/m); ; 
Morison['M2N2MAGyi']          = False     # (N-m/m); ; 
Morison['M2N3MAGyi']          = False     # (N-m/m); ; 
Morison['M2N4MAGyi']          = False     # (N-m/m); ; 
Morison['M2N5MAGyi']          = False     # (N-m/m); ; 
Morison['M2N6MAGyi']          = False     # (N-m/m); ; 
Morison['M2N7MAGyi']          = False     # (N-m/m); ; 
Morison['M2N8MAGyi']          = False     # (N-m/m); ; 
Morison['M2N9MAGyi']          = False     # (N-m/m); ; 
Morison['M3N1MAGyi']          = False     # (N-m/m); ; 
Morison['M3N2MAGyi']          = False     # (N-m/m); ; 
Morison['M3N3MAGyi']          = False     # (N-m/m); ; 
Morison['M3N4MAGyi']          = False     # (N-m/m); ; 
Morison['M3N5MAGyi']          = False     # (N-m/m); ; 
Morison['M3N6MAGyi']          = False     # (N-m/m); ; 
Morison['M3N7MAGyi']          = False     # (N-m/m); ; 
Morison['M3N8MAGyi']          = False     # (N-m/m); ; 
Morison['M3N9MAGyi']          = False     # (N-m/m); ; 
Morison['M4N1MAGyi']          = False     # (N-m/m); ; 
Morison['M4N2MAGyi']          = False     # (N-m/m); ; 
Morison['M4N3MAGyi']          = False     # (N-m/m); ; 
Morison['M4N4MAGyi']          = False     # (N-m/m); ; 
Morison['M4N5MAGyi']          = False     # (N-m/m); ; 
Morison['M4N6MAGyi']          = False     # (N-m/m); ; 
Morison['M4N7MAGyi']          = False     # (N-m/m); ; 
Morison['M4N8MAGyi']          = False     # (N-m/m); ; 
Morison['M4N9MAGyi']          = False     # (N-m/m); ; 
Morison['M5N1MAGyi']          = False     # (N-m/m); ; 
Morison['M5N2MAGyi']          = False     # (N-m/m); ; 
Morison['M5N3MAGyi']          = False     # (N-m/m); ; 
Morison['M5N4MAGyi']          = False     # (N-m/m); ; 
Morison['M5N5MAGyi']          = False     # (N-m/m); ; 
Morison['M5N6MAGyi']          = False     # (N-m/m); ; 
Morison['M5N7MAGyi']          = False     # (N-m/m); ; 
Morison['M5N8MAGyi']          = False     # (N-m/m); ; 
Morison['M5N9MAGyi']          = False     # (N-m/m); ; 
Morison['M6N1MAGyi']          = False     # (N-m/m); ; 
Morison['M6N2MAGyi']          = False     # (N-m/m); ; 
Morison['M6N3MAGyi']          = False     # (N-m/m); ; 
Morison['M6N4MAGyi']          = False     # (N-m/m); ; 
Morison['M6N5MAGyi']          = False     # (N-m/m); ; 
Morison['M6N6MAGyi']          = False     # (N-m/m); ; 
Morison['M6N7MAGyi']          = False     # (N-m/m); ; 
Morison['M6N8MAGyi']          = False     # (N-m/m); ; 
Morison['M6N9MAGyi']          = False     # (N-m/m); ; 
Morison['M7N1MAGyi']          = False     # (N-m/m); ; 
Morison['M7N2MAGyi']          = False     # (N-m/m); ; 
Morison['M7N3MAGyi']          = False     # (N-m/m); ; 
Morison['M7N4MAGyi']          = False     # (N-m/m); ; 
Morison['M7N5MAGyi']          = False     # (N-m/m); ; 
Morison['M7N6MAGyi']          = False     # (N-m/m); ; 
Morison['M7N7MAGyi']          = False     # (N-m/m); ; 
Morison['M7N8MAGyi']          = False     # (N-m/m); ; 
Morison['M7N9MAGyi']          = False     # (N-m/m); ; 
Morison['M8N1MAGyi']          = False     # (N-m/m); ; 
Morison['M8N2MAGyi']          = False     # (N-m/m); ; 
Morison['M8N3MAGyi']          = False     # (N-m/m); ; 
Morison['M8N4MAGyi']          = False     # (N-m/m); ; 
Morison['M8N5MAGyi']          = False     # (N-m/m); ; 
Morison['M8N6MAGyi']          = False     # (N-m/m); ; 
Morison['M8N7MAGyi']          = False     # (N-m/m); ; 
Morison['M8N8MAGyi']          = False     # (N-m/m); ; 
Morison['M8N9MAGyi']          = False     # (N-m/m); ; 
Morison['M9N1MAGyi']          = False     # (N-m/m); ; 
Morison['M9N2MAGyi']          = False     # (N-m/m); ; 
Morison['M9N3MAGyi']          = False     # (N-m/m); ; 
Morison['M9N4MAGyi']          = False     # (N-m/m); ; 
Morison['M9N5MAGyi']          = False     # (N-m/m); ; 
Morison['M9N6MAGyi']          = False     # (N-m/m); ; 
Morison['M9N7MAGyi']          = False     # (N-m/m); ; 
Morison['M9N8MAGyi']          = False     # (N-m/m); ; 
Morison['M9N9MAGyi']          = False     # (N-m/m); ; 
Morison['M1N1MAGzi']          = False     # (N-m/m); z-component of the distributed marine growth mass inertia moment, expressed in the inertial coordinate system; 
Morison['M1N2MAGzi']          = False     # (N-m/m); ; 
Morison['M1N3MAGzi']          = False     # (N-m/m); ; 
Morison['M1N4MAGzi']          = False     # (N-m/m); ; 
Morison['M1N5MAGzi']          = False     # (N-m/m); ; 
Morison['M1N6MAGzi']          = False     # (N-m/m); ; 
Morison['M1N7MAGzi']          = False     # (N-m/m); ; 
Morison['M1N8MAGzi']          = False     # (N-m/m); ; 
Morison['M1N9MAGzi']          = False     # (N-m/m); ; 
Morison['M2N1MAGzi']          = False     # (N-m/m); ; 
Morison['M2N2MAGzi']          = False     # (N-m/m); ; 
Morison['M2N3MAGzi']          = False     # (N-m/m); ; 
Morison['M2N4MAGzi']          = False     # (N-m/m); ; 
Morison['M2N5MAGzi']          = False     # (N-m/m); ; 
Morison['M2N6MAGzi']          = False     # (N-m/m); ; 
Morison['M2N7MAGzi']          = False     # (N-m/m); ; 
Morison['M2N8MAGzi']          = False     # (N-m/m); ; 
Morison['M2N9MAGzi']          = False     # (N-m/m); ; 
Morison['M3N1MAGzi']          = False     # (N-m/m); ; 
Morison['M3N2MAGzi']          = False     # (N-m/m); ; 
Morison['M3N3MAGzi']          = False     # (N-m/m); ; 
Morison['M3N4MAGzi']          = False     # (N-m/m); ; 
Morison['M3N5MAGzi']          = False     # (N-m/m); ; 
Morison['M3N6MAGzi']          = False     # (N-m/m); ; 
Morison['M3N7MAGzi']          = False     # (N-m/m); ; 
Morison['M3N8MAGzi']          = False     # (N-m/m); ; 
Morison['M3N9MAGzi']          = False     # (N-m/m); ; 
Morison['M4N1MAGzi']          = False     # (N-m/m); ; 
Morison['M4N2MAGzi']          = False     # (N-m/m); ; 
Morison['M4N3MAGzi']          = False     # (N-m/m); ; 
Morison['M4N4MAGzi']          = False     # (N-m/m); ; 
Morison['M4N5MAGzi']          = False     # (N-m/m); ; 
Morison['M4N6MAGzi']          = False     # (N-m/m); ; 
Morison['M4N7MAGzi']          = False     # (N-m/m); ; 
Morison['M4N8MAGzi']          = False     # (N-m/m); ; 
Morison['M4N9MAGzi']          = False     # (N-m/m); ; 
Morison['M5N1MAGzi']          = False     # (N-m/m); ; 
Morison['M5N2MAGzi']          = False     # (N-m/m); ; 
Morison['M5N3MAGzi']          = False     # (N-m/m); ; 
Morison['M5N4MAGzi']          = False     # (N-m/m); ; 
Morison['M5N5MAGzi']          = False     # (N-m/m); ; 
Morison['M5N6MAGzi']          = False     # (N-m/m); ; 
Morison['M5N7MAGzi']          = False     # (N-m/m); ; 
Morison['M5N8MAGzi']          = False     # (N-m/m); ; 
Morison['M5N9MAGzi']          = False     # (N-m/m); ; 
Morison['M6N1MAGzi']          = False     # (N-m/m); ; 
Morison['M6N2MAGzi']          = False     # (N-m/m); ; 
Morison['M6N3MAGzi']          = False     # (N-m/m); ; 
Morison['M6N4MAGzi']          = False     # (N-m/m); ; 
Morison['M6N5MAGzi']          = False     # (N-m/m); ; 
Morison['M6N6MAGzi']          = False     # (N-m/m); ; 
Morison['M6N7MAGzi']          = False     # (N-m/m); ; 
Morison['M6N8MAGzi']          = False     # (N-m/m); ; 
Morison['M6N9MAGzi']          = False     # (N-m/m); ; 
Morison['M7N1MAGzi']          = False     # (N-m/m); ; 
Morison['M7N2MAGzi']          = False     # (N-m/m); ; 
Morison['M7N3MAGzi']          = False     # (N-m/m); ; 
Morison['M7N4MAGzi']          = False     # (N-m/m); ; 
Morison['M7N5MAGzi']          = False     # (N-m/m); ; 
Morison['M7N6MAGzi']          = False     # (N-m/m); ; 
Morison['M7N7MAGzi']          = False     # (N-m/m); ; 
Morison['M7N8MAGzi']          = False     # (N-m/m); ; 
Morison['M7N9MAGzi']          = False     # (N-m/m); ; 
Morison['M8N1MAGzi']          = False     # (N-m/m); ; 
Morison['M8N2MAGzi']          = False     # (N-m/m); ; 
Morison['M8N3MAGzi']          = False     # (N-m/m); ; 
Morison['M8N4MAGzi']          = False     # (N-m/m); ; 
Morison['M8N5MAGzi']          = False     # (N-m/m); ; 
Morison['M8N6MAGzi']          = False     # (N-m/m); ; 
Morison['M8N7MAGzi']          = False     # (N-m/m); ; 
Morison['M8N8MAGzi']          = False     # (N-m/m); ; 
Morison['M8N9MAGzi']          = False     # (N-m/m); ; 
Morison['M9N1MAGzi']          = False     # (N-m/m); ; 
Morison['M9N2MAGzi']          = False     # (N-m/m); ; 
Morison['M9N3MAGzi']          = False     # (N-m/m); ; 
Morison['M9N4MAGzi']          = False     # (N-m/m); ; 
Morison['M9N5MAGzi']          = False     # (N-m/m); ; 
Morison['M9N6MAGzi']          = False     # (N-m/m); ; 
Morison['M9N7MAGzi']          = False     # (N-m/m); ; 
Morison['M9N8MAGzi']          = False     # (N-m/m); ; 
Morison['M9N9MAGzi']          = False     # (N-m/m); ; 
Morison['M1N1FAFxi']          = False     # (N/m); x-component of the distributed flooding/ballasting mass inertia force, expressed in the inertial coordinate system; 
Morison['M1N2FAFxi']          = False     # (N/m); ; 
Morison['M1N3FAFxi']          = False     # (N/m); ; 
Morison['M1N4FAFxi']          = False     # (N/m); ; 
Morison['M1N5FAFxi']          = False     # (N/m); ; 
Morison['M1N6FAFxi']          = False     # (N/m); ; 
Morison['M1N7FAFxi']          = False     # (N/m); ; 
Morison['M1N8FAFxi']          = False     # (N/m); ; 
Morison['M1N9FAFxi']          = False     # (N/m); ; 
Morison['M2N1FAFxi']          = False     # (N/m); ; 
Morison['M2N2FAFxi']          = False     # (N/m); ; 
Morison['M2N3FAFxi']          = False     # (N/m); ; 
Morison['M2N4FAFxi']          = False     # (N/m); ; 
Morison['M2N5FAFxi']          = False     # (N/m); ; 
Morison['M2N6FAFxi']          = False     # (N/m); ; 
Morison['M2N7FAFxi']          = False     # (N/m); ; 
Morison['M2N8FAFxi']          = False     # (N/m); ; 
Morison['M2N9FAFxi']          = False     # (N/m); ; 
Morison['M3N1FAFxi']          = False     # (N/m); ; 
Morison['M3N2FAFxi']          = False     # (N/m); ; 
Morison['M3N3FAFxi']          = False     # (N/m); ; 
Morison['M3N4FAFxi']          = False     # (N/m); ; 
Morison['M3N5FAFxi']          = False     # (N/m); ; 
Morison['M3N6FAFxi']          = False     # (N/m); ; 
Morison['M3N7FAFxi']          = False     # (N/m); ; 
Morison['M3N8FAFxi']          = False     # (N/m); ; 
Morison['M3N9FAFxi']          = False     # (N/m); ; 
Morison['M4N1FAFxi']          = False     # (N/m); ; 
Morison['M4N2FAFxi']          = False     # (N/m); ; 
Morison['M4N3FAFxi']          = False     # (N/m); ; 
Morison['M4N4FAFxi']          = False     # (N/m); ; 
Morison['M4N5FAFxi']          = False     # (N/m); ; 
Morison['M4N6FAFxi']          = False     # (N/m); ; 
Morison['M4N7FAFxi']          = False     # (N/m); ; 
Morison['M4N8FAFxi']          = False     # (N/m); ; 
Morison['M4N9FAFxi']          = False     # (N/m); ; 
Morison['M5N1FAFxi']          = False     # (N/m); ; 
Morison['M5N2FAFxi']          = False     # (N/m); ; 
Morison['M5N3FAFxi']          = False     # (N/m); ; 
Morison['M5N4FAFxi']          = False     # (N/m); ; 
Morison['M5N5FAFxi']          = False     # (N/m); ; 
Morison['M5N6FAFxi']          = False     # (N/m); ; 
Morison['M5N7FAFxi']          = False     # (N/m); ; 
Morison['M5N8FAFxi']          = False     # (N/m); ; 
Morison['M5N9FAFxi']          = False     # (N/m); ; 
Morison['M6N1FAFxi']          = False     # (N/m); ; 
Morison['M6N2FAFxi']          = False     # (N/m); ; 
Morison['M6N3FAFxi']          = False     # (N/m); ; 
Morison['M6N4FAFxi']          = False     # (N/m); ; 
Morison['M6N5FAFxi']          = False     # (N/m); ; 
Morison['M6N6FAFxi']          = False     # (N/m); ; 
Morison['M6N7FAFxi']          = False     # (N/m); ; 
Morison['M6N8FAFxi']          = False     # (N/m); ; 
Morison['M6N9FAFxi']          = False     # (N/m); ; 
Morison['M7N1FAFxi']          = False     # (N/m); ; 
Morison['M7N2FAFxi']          = False     # (N/m); ; 
Morison['M7N3FAFxi']          = False     # (N/m); ; 
Morison['M7N4FAFxi']          = False     # (N/m); ; 
Morison['M7N5FAFxi']          = False     # (N/m); ; 
Morison['M7N6FAFxi']          = False     # (N/m); ; 
Morison['M7N7FAFxi']          = False     # (N/m); ; 
Morison['M7N8FAFxi']          = False     # (N/m); ; 
Morison['M7N9FAFxi']          = False     # (N/m); ; 
Morison['M8N1FAFxi']          = False     # (N/m); ; 
Morison['M8N2FAFxi']          = False     # (N/m); ; 
Morison['M8N3FAFxi']          = False     # (N/m); ; 
Morison['M8N4FAFxi']          = False     # (N/m); ; 
Morison['M8N5FAFxi']          = False     # (N/m); ; 
Morison['M8N6FAFxi']          = False     # (N/m); ; 
Morison['M8N7FAFxi']          = False     # (N/m); ; 
Morison['M8N8FAFxi']          = False     # (N/m); ; 
Morison['M8N9FAFxi']          = False     # (N/m); ; 
Morison['M9N1FAFxi']          = False     # (N/m); ; 
Morison['M9N2FAFxi']          = False     # (N/m); ; 
Morison['M9N3FAFxi']          = False     # (N/m); ; 
Morison['M9N4FAFxi']          = False     # (N/m); ; 
Morison['M9N5FAFxi']          = False     # (N/m); ; 
Morison['M9N6FAFxi']          = False     # (N/m); ; 
Morison['M9N7FAFxi']          = False     # (N/m); ; 
Morison['M9N8FAFxi']          = False     # (N/m); ; 
Morison['M9N9FAFxi']          = False     # (N/m); ; 
Morison['M1N1FAFyi']          = False     # (N/m); y-component of the distributed flooding/ballasting mass inertia force, expressed in the inertial coordinate system; 
Morison['M1N2FAFyi']          = False     # (N/m); ; 
Morison['M1N3FAFyi']          = False     # (N/m); ; 
Morison['M1N4FAFyi']          = False     # (N/m); ; 
Morison['M1N5FAFyi']          = False     # (N/m); ; 
Morison['M1N6FAFyi']          = False     # (N/m); ; 
Morison['M1N7FAFyi']          = False     # (N/m); ; 
Morison['M1N8FAFyi']          = False     # (N/m); ; 
Morison['M1N9FAFyi']          = False     # (N/m); ; 
Morison['M2N1FAFyi']          = False     # (N/m); ; 
Morison['M2N2FAFyi']          = False     # (N/m); ; 
Morison['M2N3FAFyi']          = False     # (N/m); ; 
Morison['M2N4FAFyi']          = False     # (N/m); ; 
Morison['M2N5FAFyi']          = False     # (N/m); ; 
Morison['M2N6FAFyi']          = False     # (N/m); ; 
Morison['M2N7FAFyi']          = False     # (N/m); ; 
Morison['M2N8FAFyi']          = False     # (N/m); ; 
Morison['M2N9FAFyi']          = False     # (N/m); ; 
Morison['M3N1FAFyi']          = False     # (N/m); ; 
Morison['M3N2FAFyi']          = False     # (N/m); ; 
Morison['M3N3FAFyi']          = False     # (N/m); ; 
Morison['M3N4FAFyi']          = False     # (N/m); ; 
Morison['M3N5FAFyi']          = False     # (N/m); ; 
Morison['M3N6FAFyi']          = False     # (N/m); ; 
Morison['M3N7FAFyi']          = False     # (N/m); ; 
Morison['M3N8FAFyi']          = False     # (N/m); ; 
Morison['M3N9FAFyi']          = False     # (N/m); ; 
Morison['M4N1FAFyi']          = False     # (N/m); ; 
Morison['M4N2FAFyi']          = False     # (N/m); ; 
Morison['M4N3FAFyi']          = False     # (N/m); ; 
Morison['M4N4FAFyi']          = False     # (N/m); ; 
Morison['M4N5FAFyi']          = False     # (N/m); ; 
Morison['M4N6FAFyi']          = False     # (N/m); ; 
Morison['M4N7FAFyi']          = False     # (N/m); ; 
Morison['M4N8FAFyi']          = False     # (N/m); ; 
Morison['M4N9FAFyi']          = False     # (N/m); ; 
Morison['M5N1FAFyi']          = False     # (N/m); ; 
Morison['M5N2FAFyi']          = False     # (N/m); ; 
Morison['M5N3FAFyi']          = False     # (N/m); ; 
Morison['M5N4FAFyi']          = False     # (N/m); ; 
Morison['M5N5FAFyi']          = False     # (N/m); ; 
Morison['M5N6FAFyi']          = False     # (N/m); ; 
Morison['M5N7FAFyi']          = False     # (N/m); ; 
Morison['M5N8FAFyi']          = False     # (N/m); ; 
Morison['M5N9FAFyi']          = False     # (N/m); ; 
Morison['M6N1FAFyi']          = False     # (N/m); ; 
Morison['M6N2FAFyi']          = False     # (N/m); ; 
Morison['M6N3FAFyi']          = False     # (N/m); ; 
Morison['M6N4FAFyi']          = False     # (N/m); ; 
Morison['M6N5FAFyi']          = False     # (N/m); ; 
Morison['M6N6FAFyi']          = False     # (N/m); ; 
Morison['M6N7FAFyi']          = False     # (N/m); ; 
Morison['M6N8FAFyi']          = False     # (N/m); ; 
Morison['M6N9FAFyi']          = False     # (N/m); ; 
Morison['M7N1FAFyi']          = False     # (N/m); ; 
Morison['M7N2FAFyi']          = False     # (N/m); ; 
Morison['M7N3FAFyi']          = False     # (N/m); ; 
Morison['M7N4FAFyi']          = False     # (N/m); ; 
Morison['M7N5FAFyi']          = False     # (N/m); ; 
Morison['M7N6FAFyi']          = False     # (N/m); ; 
Morison['M7N7FAFyi']          = False     # (N/m); ; 
Morison['M7N8FAFyi']          = False     # (N/m); ; 
Morison['M7N9FAFyi']          = False     # (N/m); ; 
Morison['M8N1FAFyi']          = False     # (N/m); ; 
Morison['M8N2FAFyi']          = False     # (N/m); ; 
Morison['M8N3FAFyi']          = False     # (N/m); ; 
Morison['M8N4FAFyi']          = False     # (N/m); ; 
Morison['M8N5FAFyi']          = False     # (N/m); ; 
Morison['M8N6FAFyi']          = False     # (N/m); ; 
Morison['M8N7FAFyi']          = False     # (N/m); ; 
Morison['M8N8FAFyi']          = False     # (N/m); ; 
Morison['M8N9FAFyi']          = False     # (N/m); ; 
Morison['M9N1FAFyi']          = False     # (N/m); ; 
Morison['M9N2FAFyi']          = False     # (N/m); ; 
Morison['M9N3FAFyi']          = False     # (N/m); ; 
Morison['M9N4FAFyi']          = False     # (N/m); ; 
Morison['M9N5FAFyi']          = False     # (N/m); ; 
Morison['M9N6FAFyi']          = False     # (N/m); ; 
Morison['M9N7FAFyi']          = False     # (N/m); ; 
Morison['M9N8FAFyi']          = False     # (N/m); ; 
Morison['M9N9FAFyi']          = False     # (N/m); ; 
Morison['M1N1FAFzi']          = False     # (N/m); z-component of the distributed flooding/ballasting mass inertia force, expressed in the inertial coordinate system; 
Morison['M1N2FAFzi']          = False     # (N/m); ; 
Morison['M1N3FAFzi']          = False     # (N/m); ; 
Morison['M1N4FAFzi']          = False     # (N/m); ; 
Morison['M1N5FAFzi']          = False     # (N/m); ; 
Morison['M1N6FAFzi']          = False     # (N/m); ; 
Morison['M1N7FAFzi']          = False     # (N/m); ; 
Morison['M1N8FAFzi']          = False     # (N/m); ; 
Morison['M1N9FAFzi']          = False     # (N/m); ; 
Morison['M2N1FAFzi']          = False     # (N/m); ; 
Morison['M2N2FAFzi']          = False     # (N/m); ; 
Morison['M2N3FAFzi']          = False     # (N/m); ; 
Morison['M2N4FAFzi']          = False     # (N/m); ; 
Morison['M2N5FAFzi']          = False     # (N/m); ; 
Morison['M2N6FAFzi']          = False     # (N/m); ; 
Morison['M2N7FAFzi']          = False     # (N/m); ; 
Morison['M2N8FAFzi']          = False     # (N/m); ; 
Morison['M2N9FAFzi']          = False     # (N/m); ; 
Morison['M3N1FAFzi']          = False     # (N/m); ; 
Morison['M3N2FAFzi']          = False     # (N/m); ; 
Morison['M3N3FAFzi']          = False     # (N/m); ; 
Morison['M3N4FAFzi']          = False     # (N/m); ; 
Morison['M3N5FAFzi']          = False     # (N/m); ; 
Morison['M3N6FAFzi']          = False     # (N/m); ; 
Morison['M3N7FAFzi']          = False     # (N/m); ; 
Morison['M3N8FAFzi']          = False     # (N/m); ; 
Morison['M3N9FAFzi']          = False     # (N/m); ; 
Morison['M4N1FAFzi']          = False     # (N/m); ; 
Morison['M4N2FAFzi']          = False     # (N/m); ; 
Morison['M4N3FAFzi']          = False     # (N/m); ; 
Morison['M4N4FAFzi']          = False     # (N/m); ; 
Morison['M4N5FAFzi']          = False     # (N/m); ; 
Morison['M4N6FAFzi']          = False     # (N/m); ; 
Morison['M4N7FAFzi']          = False     # (N/m); ; 
Morison['M4N8FAFzi']          = False     # (N/m); ; 
Morison['M4N9FAFzi']          = False     # (N/m); ; 
Morison['M5N1FAFzi']          = False     # (N/m); ; 
Morison['M5N2FAFzi']          = False     # (N/m); ; 
Morison['M5N3FAFzi']          = False     # (N/m); ; 
Morison['M5N4FAFzi']          = False     # (N/m); ; 
Morison['M5N5FAFzi']          = False     # (N/m); ; 
Morison['M5N6FAFzi']          = False     # (N/m); ; 
Morison['M5N7FAFzi']          = False     # (N/m); ; 
Morison['M5N8FAFzi']          = False     # (N/m); ; 
Morison['M5N9FAFzi']          = False     # (N/m); ; 
Morison['M6N1FAFzi']          = False     # (N/m); ; 
Morison['M6N2FAFzi']          = False     # (N/m); ; 
Morison['M6N3FAFzi']          = False     # (N/m); ; 
Morison['M6N4FAFzi']          = False     # (N/m); ; 
Morison['M6N5FAFzi']          = False     # (N/m); ; 
Morison['M6N6FAFzi']          = False     # (N/m); ; 
Morison['M6N7FAFzi']          = False     # (N/m); ; 
Morison['M6N8FAFzi']          = False     # (N/m); ; 
Morison['M6N9FAFzi']          = False     # (N/m); ; 
Morison['M7N1FAFzi']          = False     # (N/m); ; 
Morison['M7N2FAFzi']          = False     # (N/m); ; 
Morison['M7N3FAFzi']          = False     # (N/m); ; 
Morison['M7N4FAFzi']          = False     # (N/m); ; 
Morison['M7N5FAFzi']          = False     # (N/m); ; 
Morison['M7N6FAFzi']          = False     # (N/m); ; 
Morison['M7N7FAFzi']          = False     # (N/m); ; 
Morison['M7N8FAFzi']          = False     # (N/m); ; 
Morison['M7N9FAFzi']          = False     # (N/m); ; 
Morison['M8N1FAFzi']          = False     # (N/m); ; 
Morison['M8N2FAFzi']          = False     # (N/m); ; 
Morison['M8N3FAFzi']          = False     # (N/m); ; 
Morison['M8N4FAFzi']          = False     # (N/m); ; 
Morison['M8N5FAFzi']          = False     # (N/m); ; 
Morison['M8N6FAFzi']          = False     # (N/m); ; 
Morison['M8N7FAFzi']          = False     # (N/m); ; 
Morison['M8N8FAFzi']          = False     # (N/m); ; 
Morison['M8N9FAFzi']          = False     # (N/m); ; 
Morison['M9N1FAFzi']          = False     # (N/m); ; 
Morison['M9N2FAFzi']          = False     # (N/m); ; 
Morison['M9N3FAFzi']          = False     # (N/m); ; 
Morison['M9N4FAFzi']          = False     # (N/m); ; 
Morison['M9N5FAFzi']          = False     # (N/m); ; 
Morison['M9N6FAFzi']          = False     # (N/m); ; 
Morison['M9N7FAFzi']          = False     # (N/m); ; 
Morison['M9N8FAFzi']          = False     # (N/m); ; 
Morison['M9N9FAFzi']          = False     # (N/m); ; 
Morison['M1N1MAFxi']          = False     # (N-m/m); x-component of the distributed flooding/ballasting mass inertia moment, expressed in the inertial coordinate system; 
Morison['M1N2MAFxi']          = False     # (N-m/m); ; 
Morison['M1N3MAFxi']          = False     # (N-m/m); ; 
Morison['M1N4MAFxi']          = False     # (N-m/m); ; 
Morison['M1N5MAFxi']          = False     # (N-m/m); ; 
Morison['M1N6MAFxi']          = False     # (N-m/m); ; 
Morison['M1N7MAFxi']          = False     # (N-m/m); ; 
Morison['M1N8MAFxi']          = False     # (N-m/m); ; 
Morison['M1N9MAFxi']          = False     # (N-m/m); ; 
Morison['M2N1MAFxi']          = False     # (N-m/m); ; 
Morison['M2N2MAFxi']          = False     # (N-m/m); ; 
Morison['M2N3MAFxi']          = False     # (N-m/m); ; 
Morison['M2N4MAFxi']          = False     # (N-m/m); ; 
Morison['M2N5MAFxi']          = False     # (N-m/m); ; 
Morison['M2N6MAFxi']          = False     # (N-m/m); ; 
Morison['M2N7MAFxi']          = False     # (N-m/m); ; 
Morison['M2N8MAFxi']          = False     # (N-m/m); ; 
Morison['M2N9MAFxi']          = False     # (N-m/m); ; 
Morison['M3N1MAFxi']          = False     # (N-m/m); ; 
Morison['M3N2MAFxi']          = False     # (N-m/m); ; 
Morison['M3N3MAFxi']          = False     # (N-m/m); ; 
Morison['M3N4MAFxi']          = False     # (N-m/m); ; 
Morison['M3N5MAFxi']          = False     # (N-m/m); ; 
Morison['M3N6MAFxi']          = False     # (N-m/m); ; 
Morison['M3N7MAFxi']          = False     # (N-m/m); ; 
Morison['M3N8MAFxi']          = False     # (N-m/m); ; 
Morison['M3N9MAFxi']          = False     # (N-m/m); ; 
Morison['M4N1MAFxi']          = False     # (N-m/m); ; 
Morison['M4N2MAFxi']          = False     # (N-m/m); ; 
Morison['M4N3MAFxi']          = False     # (N-m/m); ; 
Morison['M4N4MAFxi']          = False     # (N-m/m); ; 
Morison['M4N5MAFxi']          = False     # (N-m/m); ; 
Morison['M4N6MAFxi']          = False     # (N-m/m); ; 
Morison['M4N7MAFxi']          = False     # (N-m/m); ; 
Morison['M4N8MAFxi']          = False     # (N-m/m); ; 
Morison['M4N9MAFxi']          = False     # (N-m/m); ; 
Morison['M5N1MAFxi']          = False     # (N-m/m); ; 
Morison['M5N2MAFxi']          = False     # (N-m/m); ; 
Morison['M5N3MAFxi']          = False     # (N-m/m); ; 
Morison['M5N4MAFxi']          = False     # (N-m/m); ; 
Morison['M5N5MAFxi']          = False     # (N-m/m); ; 
Morison['M5N6MAFxi']          = False     # (N-m/m); ; 
Morison['M5N7MAFxi']          = False     # (N-m/m); ; 
Morison['M5N8MAFxi']          = False     # (N-m/m); ; 
Morison['M5N9MAFxi']          = False     # (N-m/m); ; 
Morison['M6N1MAFxi']          = False     # (N-m/m); ; 
Morison['M6N2MAFxi']          = False     # (N-m/m); ; 
Morison['M6N3MAFxi']          = False     # (N-m/m); ; 
Morison['M6N4MAFxi']          = False     # (N-m/m); ; 
Morison['M6N5MAFxi']          = False     # (N-m/m); ; 
Morison['M6N6MAFxi']          = False     # (N-m/m); ; 
Morison['M6N7MAFxi']          = False     # (N-m/m); ; 
Morison['M6N8MAFxi']          = False     # (N-m/m); ; 
Morison['M6N9MAFxi']          = False     # (N-m/m); ; 
Morison['M7N1MAFxi']          = False     # (N-m/m); ; 
Morison['M7N2MAFxi']          = False     # (N-m/m); ; 
Morison['M7N3MAFxi']          = False     # (N-m/m); ; 
Morison['M7N4MAFxi']          = False     # (N-m/m); ; 
Morison['M7N5MAFxi']          = False     # (N-m/m); ; 
Morison['M7N6MAFxi']          = False     # (N-m/m); ; 
Morison['M7N7MAFxi']          = False     # (N-m/m); ; 
Morison['M7N8MAFxi']          = False     # (N-m/m); ; 
Morison['M7N9MAFxi']          = False     # (N-m/m); ; 
Morison['M8N1MAFxi']          = False     # (N-m/m); ; 
Morison['M8N2MAFxi']          = False     # (N-m/m); ; 
Morison['M8N3MAFxi']          = False     # (N-m/m); ; 
Morison['M8N4MAFxi']          = False     # (N-m/m); ; 
Morison['M8N5MAFxi']          = False     # (N-m/m); ; 
Morison['M8N6MAFxi']          = False     # (N-m/m); ; 
Morison['M8N7MAFxi']          = False     # (N-m/m); ; 
Morison['M8N8MAFxi']          = False     # (N-m/m); ; 
Morison['M8N9MAFxi']          = False     # (N-m/m); ; 
Morison['M9N1MAFxi']          = False     # (N-m/m); ; 
Morison['M9N2MAFxi']          = False     # (N-m/m); ; 
Morison['M9N3MAFxi']          = False     # (N-m/m); ; 
Morison['M9N4MAFxi']          = False     # (N-m/m); ; 
Morison['M9N5MAFxi']          = False     # (N-m/m); ; 
Morison['M9N6MAFxi']          = False     # (N-m/m); ; 
Morison['M9N7MAFxi']          = False     # (N-m/m); ; 
Morison['M9N8MAFxi']          = False     # (N-m/m); ; 
Morison['M9N9MAFxi']          = False     # (N-m/m); ; 
Morison['M1N1MAFyi']          = False     # (N-m/m); y-component of the distributed flooding/ballasting mass inertia moment, expressed in the inertial coordinate system; 
Morison['M1N2MAFyi']          = False     # (N-m/m); ; 
Morison['M1N3MAFyi']          = False     # (N-m/m); ; 
Morison['M1N4MAFyi']          = False     # (N-m/m); ; 
Morison['M1N5MAFyi']          = False     # (N-m/m); ; 
Morison['M1N6MAFyi']          = False     # (N-m/m); ; 
Morison['M1N7MAFyi']          = False     # (N-m/m); ; 
Morison['M1N8MAFyi']          = False     # (N-m/m); ; 
Morison['M1N9MAFyi']          = False     # (N-m/m); ; 
Morison['M2N1MAFyi']          = False     # (N-m/m); ; 
Morison['M2N2MAFyi']          = False     # (N-m/m); ; 
Morison['M2N3MAFyi']          = False     # (N-m/m); ; 
Morison['M2N4MAFyi']          = False     # (N-m/m); ; 
Morison['M2N5MAFyi']          = False     # (N-m/m); ; 
Morison['M2N6MAFyi']          = False     # (N-m/m); ; 
Morison['M2N7MAFyi']          = False     # (N-m/m); ; 
Morison['M2N8MAFyi']          = False     # (N-m/m); ; 
Morison['M2N9MAFyi']          = False     # (N-m/m); ; 
Morison['M3N1MAFyi']          = False     # (N-m/m); ; 
Morison['M3N2MAFyi']          = False     # (N-m/m); ; 
Morison['M3N3MAFyi']          = False     # (N-m/m); ; 
Morison['M3N4MAFyi']          = False     # (N-m/m); ; 
Morison['M3N5MAFyi']          = False     # (N-m/m); ; 
Morison['M3N6MAFyi']          = False     # (N-m/m); ; 
Morison['M3N7MAFyi']          = False     # (N-m/m); ; 
Morison['M3N8MAFyi']          = False     # (N-m/m); ; 
Morison['M3N9MAFyi']          = False     # (N-m/m); ; 
Morison['M4N1MAFyi']          = False     # (N-m/m); ; 
Morison['M4N2MAFyi']          = False     # (N-m/m); ; 
Morison['M4N3MAFyi']          = False     # (N-m/m); ; 
Morison['M4N4MAFyi']          = False     # (N-m/m); ; 
Morison['M4N5MAFyi']          = False     # (N-m/m); ; 
Morison['M4N6MAFyi']          = False     # (N-m/m); ; 
Morison['M4N7MAFyi']          = False     # (N-m/m); ; 
Morison['M4N8MAFyi']          = False     # (N-m/m); ; 
Morison['M4N9MAFyi']          = False     # (N-m/m); ; 
Morison['M5N1MAFyi']          = False     # (N-m/m); ; 
Morison['M5N2MAFyi']          = False     # (N-m/m); ; 
Morison['M5N3MAFyi']          = False     # (N-m/m); ; 
Morison['M5N4MAFyi']          = False     # (N-m/m); ; 
Morison['M5N5MAFyi']          = False     # (N-m/m); ; 
Morison['M5N6MAFyi']          = False     # (N-m/m); ; 
Morison['M5N7MAFyi']          = False     # (N-m/m); ; 
Morison['M5N8MAFyi']          = False     # (N-m/m); ; 
Morison['M5N9MAFyi']          = False     # (N-m/m); ; 
Morison['M6N1MAFyi']          = False     # (N-m/m); ; 
Morison['M6N2MAFyi']          = False     # (N-m/m); ; 
Morison['M6N3MAFyi']          = False     # (N-m/m); ; 
Morison['M6N4MAFyi']          = False     # (N-m/m); ; 
Morison['M6N5MAFyi']          = False     # (N-m/m); ; 
Morison['M6N6MAFyi']          = False     # (N-m/m); ; 
Morison['M6N7MAFyi']          = False     # (N-m/m); ; 
Morison['M6N8MAFyi']          = False     # (N-m/m); ; 
Morison['M6N9MAFyi']          = False     # (N-m/m); ; 
Morison['M7N1MAFyi']          = False     # (N-m/m); ; 
Morison['M7N2MAFyi']          = False     # (N-m/m); ; 
Morison['M7N3MAFyi']          = False     # (N-m/m); ; 
Morison['M7N4MAFyi']          = False     # (N-m/m); ; 
Morison['M7N5MAFyi']          = False     # (N-m/m); ; 
Morison['M7N6MAFyi']          = False     # (N-m/m); ; 
Morison['M7N7MAFyi']          = False     # (N-m/m); ; 
Morison['M7N8MAFyi']          = False     # (N-m/m); ; 
Morison['M7N9MAFyi']          = False     # (N-m/m); ; 
Morison['M8N1MAFyi']          = False     # (N-m/m); ; 
Morison['M8N2MAFyi']          = False     # (N-m/m); ; 
Morison['M8N3MAFyi']          = False     # (N-m/m); ; 
Morison['M8N4MAFyi']          = False     # (N-m/m); ; 
Morison['M8N5MAFyi']          = False     # (N-m/m); ; 
Morison['M8N6MAFyi']          = False     # (N-m/m); ; 
Morison['M8N7MAFyi']          = False     # (N-m/m); ; 
Morison['M8N8MAFyi']          = False     # (N-m/m); ; 
Morison['M8N9MAFyi']          = False     # (N-m/m); ; 
Morison['M9N1MAFyi']          = False     # (N-m/m); ; 
Morison['M9N2MAFyi']          = False     # (N-m/m); ; 
Morison['M9N3MAFyi']          = False     # (N-m/m); ; 
Morison['M9N4MAFyi']          = False     # (N-m/m); ; 
Morison['M9N5MAFyi']          = False     # (N-m/m); ; 
Morison['M9N6MAFyi']          = False     # (N-m/m); ; 
Morison['M9N7MAFyi']          = False     # (N-m/m); ; 
Morison['M9N8MAFyi']          = False     # (N-m/m); ; 
Morison['M9N9MAFyi']          = False     # (N-m/m); ; 
Morison['M1N1MAFzi']          = False     # (N-m/m); z-component of the distributed flooding/ballasting mass inertia moment, expressed in the inertial coordinate system; 
Morison['M1N2MAFzi']          = False     # (N-m/m); ; 
Morison['M1N3MAFzi']          = False     # (N-m/m); ; 
Morison['M1N4MAFzi']          = False     # (N-m/m); ; 
Morison['M1N5MAFzi']          = False     # (N-m/m); ; 
Morison['M1N6MAFzi']          = False     # (N-m/m); ; 
Morison['M1N7MAFzi']          = False     # (N-m/m); ; 
Morison['M1N8MAFzi']          = False     # (N-m/m); ; 
Morison['M1N9MAFzi']          = False     # (N-m/m); ; 
Morison['M2N1MAFzi']          = False     # (N-m/m); ; 
Morison['M2N2MAFzi']          = False     # (N-m/m); ; 
Morison['M2N3MAFzi']          = False     # (N-m/m); ; 
Morison['M2N4MAFzi']          = False     # (N-m/m); ; 
Morison['M2N5MAFzi']          = False     # (N-m/m); ; 
Morison['M2N6MAFzi']          = False     # (N-m/m); ; 
Morison['M2N7MAFzi']          = False     # (N-m/m); ; 
Morison['M2N8MAFzi']          = False     # (N-m/m); ; 
Morison['M2N9MAFzi']          = False     # (N-m/m); ; 
Morison['M3N1MAFzi']          = False     # (N-m/m); ; 
Morison['M3N2MAFzi']          = False     # (N-m/m); ; 
Morison['M3N3MAFzi']          = False     # (N-m/m); ; 
Morison['M3N4MAFzi']          = False     # (N-m/m); ; 
Morison['M3N5MAFzi']          = False     # (N-m/m); ; 
Morison['M3N6MAFzi']          = False     # (N-m/m); ; 
Morison['M3N7MAFzi']          = False     # (N-m/m); ; 
Morison['M3N8MAFzi']          = False     # (N-m/m); ; 
Morison['M3N9MAFzi']          = False     # (N-m/m); ; 
Morison['M4N1MAFzi']          = False     # (N-m/m); ; 
Morison['M4N2MAFzi']          = False     # (N-m/m); ; 
Morison['M4N3MAFzi']          = False     # (N-m/m); ; 
Morison['M4N4MAFzi']          = False     # (N-m/m); ; 
Morison['M4N5MAFzi']          = False     # (N-m/m); ; 
Morison['M4N6MAFzi']          = False     # (N-m/m); ; 
Morison['M4N7MAFzi']          = False     # (N-m/m); ; 
Morison['M4N8MAFzi']          = False     # (N-m/m); ; 
Morison['M4N9MAFzi']          = False     # (N-m/m); ; 
Morison['M5N1MAFzi']          = False     # (N-m/m); ; 
Morison['M5N2MAFzi']          = False     # (N-m/m); ; 
Morison['M5N3MAFzi']          = False     # (N-m/m); ; 
Morison['M5N4MAFzi']          = False     # (N-m/m); ; 
Morison['M5N5MAFzi']          = False     # (N-m/m); ; 
Morison['M5N6MAFzi']          = False     # (N-m/m); ; 
Morison['M5N7MAFzi']          = False     # (N-m/m); ; 
Morison['M5N8MAFzi']          = False     # (N-m/m); ; 
Morison['M5N9MAFzi']          = False     # (N-m/m); ; 
Morison['M6N1MAFzi']          = False     # (N-m/m); ; 
Morison['M6N2MAFzi']          = False     # (N-m/m); ; 
Morison['M6N3MAFzi']          = False     # (N-m/m); ; 
Morison['M6N4MAFzi']          = False     # (N-m/m); ; 
Morison['M6N5MAFzi']          = False     # (N-m/m); ; 
Morison['M6N6MAFzi']          = False     # (N-m/m); ; 
Morison['M6N7MAFzi']          = False     # (N-m/m); ; 
Morison['M6N8MAFzi']          = False     # (N-m/m); ; 
Morison['M6N9MAFzi']          = False     # (N-m/m); ; 
Morison['M7N1MAFzi']          = False     # (N-m/m); ; 
Morison['M7N2MAFzi']          = False     # (N-m/m); ; 
Morison['M7N3MAFzi']          = False     # (N-m/m); ; 
Morison['M7N4MAFzi']          = False     # (N-m/m); ; 
Morison['M7N5MAFzi']          = False     # (N-m/m); ; 
Morison['M7N6MAFzi']          = False     # (N-m/m); ; 
Morison['M7N7MAFzi']          = False     # (N-m/m); ; 
Morison['M7N8MAFzi']          = False     # (N-m/m); ; 
Morison['M7N9MAFzi']          = False     # (N-m/m); ; 
Morison['M8N1MAFzi']          = False     # (N-m/m); ; 
Morison['M8N2MAFzi']          = False     # (N-m/m); ; 
Morison['M8N3MAFzi']          = False     # (N-m/m); ; 
Morison['M8N4MAFzi']          = False     # (N-m/m); ; 
Morison['M8N5MAFzi']          = False     # (N-m/m); ; 
Morison['M8N6MAFzi']          = False     # (N-m/m); ; 
Morison['M8N7MAFzi']          = False     # (N-m/m); ; 
Morison['M8N8MAFzi']          = False     # (N-m/m); ; 
Morison['M8N9MAFzi']          = False     # (N-m/m); ; 
Morison['M9N1MAFzi']          = False     # (N-m/m); ; 
Morison['M9N2MAFzi']          = False     # (N-m/m); ; 
Morison['M9N3MAFzi']          = False     # (N-m/m); ; 
Morison['M9N4MAFzi']          = False     # (N-m/m); ; 
Morison['M9N5MAFzi']          = False     # (N-m/m); ; 
Morison['M9N6MAFzi']          = False     # (N-m/m); ; 
Morison['M9N7MAFzi']          = False     # (N-m/m); ; 
Morison['M9N8MAFzi']          = False     # (N-m/m); ; 
Morison['M9N9MAFzi']          = False     # (N-m/m); ; 

# Joint-level Wave Kinematics 
Morison['J1Vxi']              = False     # (m/s); fluid velocity at the joint; 
Morison['J2Vxi']              = False     # (m/s); ; 
Morison['J3Vxi']              = False     # (m/s); ; 
Morison['J4Vxi']              = False     # (m/s); ; 
Morison['J5Vxi']              = False     # (m/s); ; 
Morison['J6Vxi']              = False     # (m/s); ; 
Morison['J7Vxi']              = False     # (m/s); ; 
Morison['J8Vxi']              = False     # (m/s); ; 
Morison['J9Vxi']              = False     # (m/s); ; 
Morison['J1Vyi']              = False     # (m/s); ; 
Morison['J2Vyi']              = False     # (m/s); ; 
Morison['J3Vyi']              = False     # (m/s); ; 
Morison['J4Vyi']              = False     # (m/s); ; 
Morison['J5Vyi']              = False     # (m/s); ; 
Morison['J6Vyi']              = False     # (m/s); ; 
Morison['J7Vyi']              = False     # (m/s); ; 
Morison['J8Vyi']              = False     # (m/s); ; 
Morison['J9Vyi']              = False     # (m/s); ; 
Morison['J1Vzi']              = False     # (m/s); ; 
Morison['J2Vzi']              = False     # (m/s); ; 
Morison['J3Vzi']              = False     # (m/s); ; 
Morison['J4Vzi']              = False     # (m/s); ; 
Morison['J5Vzi']              = False     # (m/s); ; 
Morison['J6Vzi']              = False     # (m/s); ; 
Morison['J7Vzi']              = False     # (m/s); ; 
Morison['J8Vzi']              = False     # (m/s); ; 
Morison['J9Vzi']              = False     # (m/s); ; 
Morison['J1Axi']              = False     # (m/s^2); fluid acceleration at the joint; 
Morison['J2Axi']              = False     # (m/s^2); ; 
Morison['J3Axi']              = False     # (m/s^2); ; 
Morison['J4Axi']              = False     # (m/s^2); ; 
Morison['J5Axi']              = False     # (m/s^2); ; 
Morison['J6Axi']              = False     # (m/s^2); ; 
Morison['J7Axi']              = False     # (m/s^2); ; 
Morison['J8Axi']              = False     # (m/s^2); ; 
Morison['J9Axi']              = False     # (m/s^2); ; 
Morison['J1Ayi']              = False     # (m/s^2); ; 
Morison['J2Ayi']              = False     # (m/s^2); ; 
Morison['J3Ayi']              = False     # (m/s^2); ; 
Morison['J4Ayi']              = False     # (m/s^2); ; 
Morison['J5Ayi']              = False     # (m/s^2); ; 
Morison['J6Ayi']              = False     # (m/s^2); ; 
Morison['J7Ayi']              = False     # (m/s^2); ; 
Morison['J8Ayi']              = False     # (m/s^2); ; 
Morison['J9Ayi']              = False     # (m/s^2); ; 
Morison['J1Azi']              = False     # (m/s^2); ; 
Morison['J2Azi']              = False     # (m/s^2); ; 
Morison['J3Azi']              = False     # (m/s^2); ; 
Morison['J4Azi']              = False     # (m/s^2); ; 
Morison['J5Azi']              = False     # (m/s^2); ; 
Morison['J6Azi']              = False     # (m/s^2); ; 
Morison['J7Azi']              = False     # (m/s^2); ; 
Morison['J8Azi']              = False     # (m/s^2); ; 
Morison['J9Azi']              = False     # (m/s^2); ; 
Morison['J1DynP']             = False     # (Pa); fluid dynamic pressure at the joint; 
Morison['J2DynP']             = False     # (Pa); ; 
Morison['J3DynP']             = False     # (Pa); ; 
Morison['J4DynP']             = False     # (Pa); ; 
Morison['J5DynP']             = False     # (Pa); ; 
Morison['J6DynP']             = False     # (Pa); ; 
Morison['J7DynP']             = False     # (Pa); ; 
Morison['J8DynP']             = False     # (Pa); ; 
Morison['J9DynP']             = False     # (Pa); ; 
Morison['J1WaveElev']         = False     # (m); total wave elevation at the X,Y location of the joint; 
Morison['J2WaveElev']         = False     # (m); ; 
Morison['J3WaveElev']         = False     # (m); ; 
Morison['J4WaveElev']         = False     # (m); ; 
Morison['J5WaveElev']         = False     # (m); ; 
Morison['J6WaveElev']         = False     # (m); ; 
Morison['J7WaveElev']         = False     # (m); ; 
Morison['J8WaveElev']         = False     # (m); ; 
Morison['J9WaveElev']         = False     # (m); ; 
Morison['J1WaveElv1']         = False     # (m); wave elevation at the X,Y location of the joint due to 1st order effects; 
Morison['J2WaveElv1']         = False     # (m); ; 
Morison['J3WaveElv1']         = False     # (m); ; 
Morison['J4WaveElv1']         = False     # (m); ; 
Morison['J5WaveElv1']         = False     # (m); ; 
Morison['J6WaveElv1']         = False     # (m); ; 
Morison['J7WaveElv1']         = False     # (m); ; 
Morison['J8WaveElv1']         = False     # (m); ; 
Morison['J9WaveElv1']         = False     # (m); ; 
Morison['J1WaveElv2']         = False     # (m); wave elevation at the X,Y location of the joint due to 2nd order effects; 
Morison['J2WaveElv2']         = False     # (m); ; 
Morison['J3WaveElv2']         = False     # (m); ; 
Morison['J4WaveElv2']         = False     # (m); ; 
Morison['J5WaveElv2']         = False     # (m); ; 
Morison['J6WaveElv2']         = False     # (m); ; 
Morison['J7WaveElv2']         = False     # (m); ; 
Morison['J8WaveElv2']         = False     # (m); ; 
Morison['J9WaveElv2']         = False     # (m); ; 
Morison['J1STVxi']            = False     # (m/s); structural translational velocity at the joint; 
Morison['J2STVxi']            = False     # (m/s); ; 
Morison['J3STVxi']            = False     # (m/s); ; 
Morison['J4STVxi']            = False     # (m/s); ; 
Morison['J5STVxi']            = False     # (m/s); ; 
Morison['J6STVxi']            = False     # (m/s); ; 
Morison['J7STVxi']            = False     # (m/s); ; 
Morison['J8STVxi']            = False     # (m/s); ; 
Morison['J9STVxi']            = False     # (m/s); ; 
Morison['J1STVyi']            = False     # (m/s); ; 
Morison['J2STVyi']            = False     # (m/s); ; 
Morison['J3STVyi']            = False     # (m/s); ; 
Morison['J4STVyi']            = False     # (m/s); ; 
Morison['J5STVyi']            = False     # (m/s); ; 
Morison['J6STVyi']            = False     # (m/s); ; 
Morison['J7STVyi']            = False     # (m/s); ; 
Morison['J8STVyi']            = False     # (m/s); ; 
Morison['J9STVyi']            = False     # (m/s); ; 
Morison['J1STVzi']            = False     # (m/s); ; 
Morison['J2STVzi']            = False     # (m/s); ; 
Morison['J3STVzi']            = False     # (m/s); ; 
Morison['J4STVzi']            = False     # (m/s); ; 
Morison['J5STVzi']            = False     # (m/s); ; 
Morison['J6STVzi']            = False     # (m/s); ; 
Morison['J7STVzi']            = False     # (m/s); ; 
Morison['J8STVzi']            = False     # (m/s); ; 
Morison['J9STVzi']            = False     # (m/s); ; 
Morison['J1STAxi']            = False     # (m/s^2); structural translational acceleration at the joint; 
Morison['J2STAxi']            = False     # (m/s^2); ; 
Morison['J3STAxi']            = False     # (m/s^2); ; 
Morison['J4STAxi']            = False     # (m/s^2); ; 
Morison['J5STAxi']            = False     # (m/s^2); ; 
Morison['J6STAxi']            = False     # (m/s^2); ; 
Morison['J7STAxi']            = False     # (m/s^2); ; 
Morison['J8STAxi']            = False     # (m/s^2); ; 
Morison['J9STAxi']            = False     # (m/s^2); ; 
Morison['J1STAyi']            = False     # (m/s^2); ; 
Morison['J2STAyi']            = False     # (m/s^2); ; 
Morison['J3STAyi']            = False     # (m/s^2); ; 
Morison['J4STAyi']            = False     # (m/s^2); ; 
Morison['J5STAyi']            = False     # (m/s^2); ; 
Morison['J6STAyi']            = False     # (m/s^2); ; 
Morison['J7STAyi']            = False     # (m/s^2); ; 
Morison['J8STAyi']            = False     # (m/s^2); ; 
Morison['J9STAyi']            = False     # (m/s^2); ; 
Morison['J1STAzi']            = False     # (m/s^2); ; 
Morison['J2STAzi']            = False     # (m/s^2); ; 
Morison['J3STAzi']            = False     # (m/s^2); ; 
Morison['J4STAzi']            = False     # (m/s^2); ; 
Morison['J5STAzi']            = False     # (m/s^2); ; 
Morison['J6STAzi']            = False     # (m/s^2); ; 
Morison['J7STAzi']            = False     # (m/s^2); ; 
Morison['J8STAzi']            = False     # (m/s^2); ; 
Morison['J9STAzi']            = False     # (m/s^2); ; 

# Joint Loads
Morison['J1FDxi']             = False     # (N); axial viscous-drag forces; 
Morison['J2FDxi']             = False     # (N); ; 
Morison['J3FDxi']             = False     # (N); ; 
Morison['J4FDxi']             = False     # (N); ; 
Morison['J5FDxi']             = False     # (N); ; 
Morison['J6FDxi']             = False     # (N); ; 
Morison['J7FDxi']             = False     # (N); ; 
Morison['J8FDxi']             = False     # (N); ; 
Morison['J9FDxi']             = False     # (N); ; 
Morison['J1FDyi']             = False     # (N); ; 
Morison['J2FDyi']             = False     # (N); ; 
Morison['J3FDyi']             = False     # (N); ; 
Morison['J4FDyi']             = False     # (N); ; 
Morison['J5FDyi']             = False     # (N); ; 
Morison['J6FDyi']             = False     # (N); ; 
Morison['J7FDyi']             = False     # (N); ; 
Morison['J8FDyi']             = False     # (N); ; 
Morison['J9FDyi']             = False     # (N); ; 
Morison['J1FDzi']             = False     # (N); ; 
Morison['J2FDzi']             = False     # (N); ; 
Morison['J3FDzi']             = False     # (N); ; 
Morison['J4FDzi']             = False     # (N); ; 
Morison['J5FDzi']             = False     # (N); ; 
Morison['J6FDzi']             = False     # (N); ; 
Morison['J7FDzi']             = False     # (N); ; 
Morison['J8FDzi']             = False     # (N); ; 
Morison['J9FDzi']             = False     # (N); ; 
Morison['J1FBxi']             = False     # (N); end-effect buoyancy forces; 
Morison['J2FBxi']             = False     # (N); ; 
Morison['J3FBxi']             = False     # (N); ; 
Morison['J4FBxi']             = False     # (N); ; 
Morison['J5FBxi']             = False     # (N); ; 
Morison['J6FBxi']             = False     # (N); ; 
Morison['J7FBxi']             = False     # (N); ; 
Morison['J8FBxi']             = False     # (N); ; 
Morison['J9FBxi']             = False     # (N); ; 
Morison['J1FByi']             = False     # (N); ; 
Morison['J2FByi']             = False     # (N); ; 
Morison['J3FByi']             = False     # (N); ; 
Morison['J4FByi']             = False     # (N); ; 
Morison['J5FByi']             = False     # (N); ; 
Morison['J6FByi']             = False     # (N); ; 
Morison['J7FByi']             = False     # (N); ; 
Morison['J8FByi']             = False     # (N); ; 
Morison['J9FByi']             = False     # (N); ; 
Morison['J1FBzi']             = False     # (N); ; 
Morison['J2FBzi']             = False     # (N); ; 
Morison['J3FBzi']             = False     # (N); ; 
Morison['J4FBzi']             = False     # (N); ; 
Morison['J5FBzi']             = False     # (N); ; 
Morison['J6FBzi']             = False     # (N); ; 
Morison['J7FBzi']             = False     # (N); ; 
Morison['J8FBzi']             = False     # (N); ; 
Morison['J9FBzi']             = False     # (N); ; 
Morison['J1MBxi']             = False     # (N-m); end-effect buoyancy moments; 
Morison['J2MBxi']             = False     # (N-m); ; 
Morison['J3MBxi']             = False     # (N-m); ; 
Morison['J4MBxi']             = False     # (N-m); ; 
Morison['J5MBxi']             = False     # (N-m); ; 
Morison['J6MBxi']             = False     # (N-m); ; 
Morison['J7MBxi']             = False     # (N-m); ; 
Morison['J8MBxi']             = False     # (N-m); ; 
Morison['J9MBxi']             = False     # (N-m); ; 
Morison['J1MByi']             = False     # (N-m); ; 
Morison['J2MByi']             = False     # (N-m); ; 
Morison['J3MByi']             = False     # (N-m); ; 
Morison['J4MByi']             = False     # (N-m); ; 
Morison['J5MByi']             = False     # (N-m); ; 
Morison['J6MByi']             = False     # (N-m); ; 
Morison['J7MByi']             = False     # (N-m); ; 
Morison['J8MByi']             = False     # (N-m); ; 
Morison['J9MByi']             = False     # (N-m); ; 
Morison['J1MBzi']             = False     # (N-m); ; 
Morison['J2MBzi']             = False     # (N-m); ; 
Morison['J3MBzi']             = False     # (N-m); ; 
Morison['J4MBzi']             = False     # (N-m); ; 
Morison['J5MBzi']             = False     # (N-m); ; 
Morison['J6MBzi']             = False     # (N-m); ; 
Morison['J7MBzi']             = False     # (N-m); ; 
Morison['J8MBzi']             = False     # (N-m); ; 
Morison['J9MBzi']             = False     # (N-m); ; 
Morison['J1FBFxi']            = False     # (N); end-effect buoyancy forces due to ballasting/flooding; 
Morison['J2FBFxi']            = False     # (N); ; 
Morison['J3FBFxi']            = False     # (N); ; 
Morison['J4FBFxi']            = False     # (N); ; 
Morison['J5FBFxi']            = False     # (N); ; 
Morison['J6FBFxi']            = False     # (N); ; 
Morison['J7FBFxi']            = False     # (N); ; 
Morison['J8FBFxi']            = False     # (N); ; 
Morison['J9FBFxi']            = False     # (N); ; 
Morison['J1FBFyi']            = False     # (N); ; 
Morison['J2FBFyi']            = False     # (N); ; 
Morison['J3FBFyi']            = False     # (N); ; 
Morison['J4FBFyi']            = False     # (N); ; 
Morison['J5FBFyi']            = False     # (N); ; 
Morison['J6FBFyi']            = False     # (N); ; 
Morison['J7FBFyi']            = False     # (N); ; 
Morison['J8FBFyi']            = False     # (N); ; 
Morison['J9FBFyi']            = False     # (N); ; 
Morison['J1FBFzi']            = False     # (N); ; 
Morison['J2FBFzi']            = False     # (N); ; 
Morison['J3FBFzi']            = False     # (N); ; 
Morison['J4FBFzi']            = False     # (N); ; 
Morison['J5FBFzi']            = False     # (N); ; 
Morison['J6FBFzi']            = False     # (N); ; 
Morison['J7FBFzi']            = False     # (N); ; 
Morison['J8FBFzi']            = False     # (N); ; 
Morison['J9FBFzi']            = False     # (N); ; 
Morison['J1MBFxi']            = False     # (N-m); end-effect buoyancy moments due to ballasting/flooding; 
Morison['J2MBFxi']            = False     # (N-m); ; 
Morison['J3MBFxi']            = False     # (N-m); ; 
Morison['J4MBFxi']            = False     # (N-m); ; 
Morison['J5MBFxi']            = False     # (N-m); ; 
Morison['J6MBFxi']            = False     # (N-m); ; 
Morison['J7MBFxi']            = False     # (N-m); ; 
Morison['J8MBFxi']            = False     # (N-m); ; 
Morison['J9MBFxi']            = False     # (N-m); ; 
Morison['J1MBFyi']            = False     # (N-m); ; 
Morison['J2MBFyi']            = False     # (N-m); ; 
Morison['J3MBFyi']            = False     # (N-m); ; 
Morison['J4MBFyi']            = False     # (N-m); ; 
Morison['J5MBFyi']            = False     # (N-m); ; 
Morison['J6MBFyi']            = False     # (N-m); ; 
Morison['J7MBFyi']            = False     # (N-m); ; 
Morison['J8MBFyi']            = False     # (N-m); ; 
Morison['J9MBFyi']            = False     # (N-m); ; 
Morison['J1MBFzi']            = False     # (N-m); ; 
Morison['J2MBFzi']            = False     # (N-m); ; 
Morison['J3MBFzi']            = False     # (N-m); ; 
Morison['J4MBFzi']            = False     # (N-m); ; 
Morison['J5MBFzi']            = False     # (N-m); ; 
Morison['J6MBFzi']            = False     # (N-m); ; 
Morison['J7MBFzi']            = False     # (N-m); ; 
Morison['J8MBFzi']            = False     # (N-m); ; 
Morison['J9MBFzi']            = False     # (N-m); ; 
Morison['J1FIxi']             = False     # (N); end-effect fluid inertia forces ; 
Morison['J2FIxi']             = False     # (N); ; 
Morison['J3FIxi']             = False     # (N); ; 
Morison['J4FIxi']             = False     # (N); ; 
Morison['J5FIxi']             = False     # (N); ; 
Morison['J6FIxi']             = False     # (N); ; 
Morison['J7FIxi']             = False     # (N); ; 
Morison['J8FIxi']             = False     # (N); ; 
Morison['J9FIxi']             = False     # (N); ; 
Morison['J1FIyi']             = False     # (N); ; 
Morison['J2FIyi']             = False     # (N); ; 
Morison['J3FIyi']             = False     # (N); ; 
Morison['J4FIyi']             = False     # (N); ; 
Morison['J5FIyi']             = False     # (N); ; 
Morison['J6FIyi']             = False     # (N); ; 
Morison['J7FIyi']             = False     # (N); ; 
Morison['J8FIyi']             = False     # (N); ; 
Morison['J9FIyi']             = False     # (N); ; 
Morison['J1FIzi']             = False     # (N); ; 
Morison['J2FIzi']             = False     # (N); ; 
Morison['J3FIzi']             = False     # (N); ; 
Morison['J4FIzi']             = False     # (N); ; 
Morison['J5FIzi']             = False     # (N); ; 
Morison['J6FIzi']             = False     # (N); ; 
Morison['J7FIzi']             = False     # (N); ; 
Morison['J8FIzi']             = False     # (N); ; 
Morison['J9FIzi']             = False     # (N); ; 
Morison['J1FAMxi']            = False     # (N); added mass forces; 
Morison['J2FAMxi']            = False     # (N); ; 
Morison['J3FAMxi']            = False     # (N); ; 
Morison['J4FAMxi']            = False     # (N); ; 
Morison['J5FAMxi']            = False     # (N); ; 
Morison['J6FAMxi']            = False     # (N); ; 
Morison['J7FAMxi']            = False     # (N); ; 
Morison['J8FAMxi']            = False     # (N); ; 
Morison['J9FAMxi']            = False     # (N); ; 
Morison['J1FAMyi']            = False     # (N); ; 
Morison['J2FAMyi']            = False     # (N); ; 
Morison['J3FAMyi']            = False     # (N); ; 
Morison['J4FAMyi']            = False     # (N); ; 
Morison['J5FAMyi']            = False     # (N); ; 
Morison['J6FAMyi']            = False     # (N); ; 
Morison['J7FAMyi']            = False     # (N); ; 
Morison['J8FAMyi']            = False     # (N); ; 
Morison['J9FAMyi']            = False     # (N); ; 
Morison['J1FAMzi']            = False     # (N); ; 
Morison['J2FAMzi']            = False     # (N); ; 
Morison['J3FAMzi']            = False     # (N); ; 
Morison['J4FAMzi']            = False     # (N); ; 
Morison['J5FAMzi']            = False     # (N); ; 
Morison['J6FAMzi']            = False     # (N); ; 
Morison['J7FAMzi']            = False     # (N); ; 
Morison['J8FAMzi']            = False     # (N); ; 
Morison['J9FAMzi']            = False     # (N); ; 
Morison['J1FAGxi']            = False     # (N); end effect marine growth inertia; 
Morison['J2FAGxi']            = False     # (N); ; 
Morison['J3FAGxi']            = False     # (N); ; 
Morison['J4FAGxi']            = False     # (N); ; 
Morison['J5FAGxi']            = False     # (N); ; 
Morison['J6FAGxi']            = False     # (N); ; 
Morison['J7FAGxi']            = False     # (N); ; 
Morison['J8FAGxi']            = False     # (N); ; 
Morison['J9FAGxi']            = False     # (N); ; 
Morison['J1FAGyi']            = False     # (N); ; 
Morison['J2FAGyi']            = False     # (N); ; 
Morison['J3FAGyi']            = False     # (N); ; 
Morison['J4FAGyi']            = False     # (N); ; 
Morison['J5FAGyi']            = False     # (N); ; 
Morison['J6FAGyi']            = False     # (N); ; 
Morison['J7FAGyi']            = False     # (N); ; 
Morison['J8FAGyi']            = False     # (N); ; 
Morison['J9FAGyi']            = False     # (N); ; 
Morison['J1FAGzi']            = False     # (N); ; 
Morison['J2FAGzi']            = False     # (N); ; 
Morison['J3FAGzi']            = False     # (N); ; 
Morison['J4FAGzi']            = False     # (N); ; 
Morison['J5FAGzi']            = False     # (N); ; 
Morison['J6FAGzi']            = False     # (N); ; 
Morison['J7FAGzi']            = False     # (N); ; 
Morison['J8FAGzi']            = False     # (N); ; 
Morison['J9FAGzi']            = False     # (N); ; 
Morison['J1MAGxi']            = False     # (N-m); ; 
Morison['J2MAGxi']            = False     # (N-m); ; 
Morison['J3MAGxi']            = False     # (N-m); ; 
Morison['J4MAGxi']            = False     # (N-m); ; 
Morison['J5MAGxi']            = False     # (N-m); ; 
Morison['J6MAGxi']            = False     # (N-m); ; 
Morison['J7MAGxi']            = False     # (N-m); ; 
Morison['J8MAGxi']            = False     # (N-m); ; 
Morison['J9MAGxi']            = False     # (N-m); ; 
Morison['J1MAGyi']            = False     # (N-m); ; 
Morison['J2MAGyi']            = False     # (N-m); ; 
Morison['J3MAGyi']            = False     # (N-m); ; 
Morison['J4MAGyi']            = False     # (N-m); ; 
Morison['J5MAGyi']            = False     # (N-m); ; 
Morison['J6MAGyi']            = False     # (N-m); ; 
Morison['J7MAGyi']            = False     # (N-m); ; 
Morison['J8MAGyi']            = False     # (N-m); ; 
Morison['J9MAGyi']            = False     # (N-m); ; 
Morison['J1MAGzi']            = False     # (N-m); ; 
Morison['J2MAGzi']            = False     # (N-m); ; 
Morison['J3MAGzi']            = False     # (N-m); ; 
Morison['J4MAGzi']            = False     # (N-m); ; 
Morison['J5MAGzi']            = False     # (N-m); ; 
Morison['J6MAGzi']            = False     # (N-m); ; 
Morison['J7MAGzi']            = False     # (N-m); ; 
Morison['J8MAGzi']            = False     # (N-m); ; 
Morison['J9MAGzi']            = False     # (N-m); ; 
Morison['J1FMGxi']            = False     # (N); end effect marine growth weight; 
Morison['J2FMGxi']            = False     # (N); ; 
Morison['J3FMGxi']            = False     # (N); ; 
Morison['J4FMGxi']            = False     # (N); ; 
Morison['J5FMGxi']            = False     # (N); ; 
Morison['J6FMGxi']            = False     # (N); ; 
Morison['J7FMGxi']            = False     # (N); ; 
Morison['J8FMGxi']            = False     # (N); ; 
Morison['J9FMGxi']            = False     # (N); ; 
Morison['J1FMGyi']            = False     # (N); ; 
Morison['J2FMGyi']            = False     # (N); ; 
Morison['J3FMGyi']            = False     # (N); ; 
Morison['J4FMGyi']            = False     # (N); ; 
Morison['J5FMGyi']            = False     # (N); ; 
Morison['J6FMGyi']            = False     # (N); ; 
Morison['J7FMGyi']            = False     # (N); ; 
Morison['J8FMGyi']            = False     # (N); ; 
Morison['J9FMGyi']            = False     # (N); ; 
Morison['J1FMGzi']            = False     # (N); ; 
Morison['J2FMGzi']            = False     # (N); ; 
Morison['J3FMGzi']            = False     # (N); ; 
Morison['J4FMGzi']            = False     # (N); ; 
Morison['J5FMGzi']            = False     # (N); ; 
Morison['J6FMGzi']            = False     # (N); ; 
Morison['J7FMGzi']            = False     # (N); ; 
Morison['J8FMGzi']            = False     # (N); ; 
Morison['J9FMGzi']            = False     # (N); ; 


""" SeaState """
SeaState = {}

# Wave Elevations
SeaState['Wave1Elev']         = False     # (m); Total (first-order plus second-order) wave elevation (global Z height) at the 1st user-requested location (location is specified in the global coordinate system); 
SeaState['Wave2Elev']         = False     # (m); Total (first-order plus second-order) wave elevation (global Z height) at the 2nd user-requested location (location is specified in the global coordinate system); 
SeaState['Wave3Elev']         = False     # (m); Total (first-order plus second-order) wave elevation (global Z height) at the 3rd user-requested location (location is specified in the global coordinate system); 
SeaState['Wave4Elev']         = False     # (m); Total (first-order plus second-order) wave elevation (global Z height) at the 4th user-requested location (location is specified in the global coordinate system); 
SeaState['Wave5Elev']         = False     # (m); Total (first-order plus second-order) wave elevation (global Z height) at the 5th user-requested location (location is specified in the global coordinate system); 
SeaState['Wave6Elev']         = False     # (m); Total (first-order plus second-order) wave elevation (global Z height) at the 6th user-requested location (location is specified in the global coordinate system); 
SeaState['Wave7Elev']         = False     # (m); Total (first-order plus second-order) wave elevation (global Z height) at the 7th user-requested location (location is specified in the global coordinate system); 
SeaState['Wave8Elev']         = False     # (m); Total (first-order plus second-order) wave elevation (global Z height) at the 8th user-requested location (location is specified in the global coordinate system); 
SeaState['Wave9Elev']         = False     # (m); Total (first-order plus second-order) wave elevation (global Z height) at the 9th user-requested location (location is specified in the global coordinate system); 
SeaState['Wave1Elv1']         = False     # (m); First-order wave elevation (global Z height) at the 1st user-requested location (location is specified in the global coordinate system); 
SeaState['Wave2Elv1']         = False     # (m); First-order wave elevation (global Z height) at the 2nd user-requested location (location is specified in the global coordinate system); 
SeaState['Wave3Elv1']         = False     # (m); First-order wave elevation (global Z height) at the 3rd user-requested location (location is specified in the global coordinate system); 
SeaState['Wave4Elv1']         = False     # (m); First-order wave elevation (global Z height) at the 4th user-requested location (location is specified in the global coordinate system); 
SeaState['Wave5Elv1']         = False     # (m); First-order wave elevation (global Z height) at the 5th user-requested location (location is specified in the global coordinate system); 
SeaState['Wave6Elv1']         = False     # (m); First-order wave elevation (global Z height) at the 6th user-requested location (location is specified in the global coordinate system); 
SeaState['Wave7Elv1']         = False     # (m); First-order wave elevation (global Z height) at the 7th user-requested location (location is specified in the global coordinate system); 
SeaState['Wave8Elv1']         = False     # (m); First-order wave elevation (global Z height) at the 8th user-requested location (location is specified in the global coordinate system); 
SeaState['Wave9Elv1']         = False     # (m); First-order wave elevation (global Z height) at the 9th user-requested location (location is specified in the global coordinate system); 
SeaState['Wave1Elv2']         = False     # (m); Second-order wave elevation (global Z height) at the 1st user-requested location (location is specified in the global coordinate system); 
SeaState['Wave2Elv2']         = False     # (m); Second-order wave elevation (global Z height) at the 2nd user-requested location (location is specified in the global coordinate system); 
SeaState['Wave3Elv2']         = False     # (m); Second-order wave elevation (global Z height) at the 3rd user-requested location (location is specified in the global coordinate system); 
SeaState['Wave4Elv2']         = False     # (m); Second-order wave elevation (global Z height) at the 4th user-requested location (location is specified in the global coordinate system); 
SeaState['Wave5Elv2']         = False     # (m); Second-order wave elevation (global Z height) at the 5th user-requested location (location is specified in the global coordinate system); 
SeaState['Wave6Elv2']         = False     # (m); Second-order wave elevation (global Z height) at the 6th user-requested location (location is specified in the global coordinate system); 
SeaState['Wave7Elv2']         = False     # (m); Second-order wave elevation (global Z height) at the 7th user-requested location (location is specified in the global coordinate system); 
SeaState['Wave8Elv2']         = False     # (m); Second-order wave elevation (global Z height) at the 8th user-requested location (location is specified in the global coordinate system); 
SeaState['Wave9Elv2']         = False     # (m); Second-order wave elevation (global Z height) at the 9th user-requested location (location is specified in the global coordinate system); 

# Wave Kinematics 
SeaState['FVel1xi']           = False     # (m/s); fluid velocity along the global x-direction at the 1st user-requested location (location is specified in the global coordinate system); 
SeaState['FVel2xi']           = False     # (m/s); fluid velocity along the global x-direction at the 2nd user-requested location (location is specified in the global coordinate system); 
SeaState['FVel3xi']           = False     # (m/s); fluid velocity along the global x-direction at the 3rd user-requested location (location is specified in the global coordinate system); 
SeaState['FVel4xi']           = False     # (m/s); fluid velocity along the global x-direction at the 4th user-requested location (location is specified in the global coordinate system); 
SeaState['FVel5xi']           = False     # (m/s); fluid velocity along the global x-direction at the 5th user-requested location (location is specified in the global coordinate system); 
SeaState['FVel6xi']           = False     # (m/s); fluid velocity along the global x-direction at the 6th user-requested location (location is specified in the global coordinate system); 
SeaState['FVel7xi']           = False     # (m/s); fluid velocity along the global x-direction at the 7th user-requested location (location is specified in the global coordinate system); 
SeaState['FVel8xi']           = False     # (m/s); fluid velocity along the global x-direction at the 8th user-requested location (location is specified in the global coordinate system); 
SeaState['FVel9xi']           = False     # (m/s); fluid velocity along the global x-direction at the 9th user-requested location (location is specified in the global coordinate system); 
SeaState['FVel1yi']           = False     # (m/s); fluid velocity along the global y-direction at the 1st user-requested location (location is specified in the global coordinate system); 
SeaState['FVel2yi']           = False     # (m/s); fluid velocity along the global y-direction at the 2nd user-requested location (location is specified in the global coordinate system); 
SeaState['FVel3yi']           = False     # (m/s); fluid velocity along the global y-direction at the 3rd user-requested location (location is specified in the global coordinate system); 
SeaState['FVel4yi']           = False     # (m/s); fluid velocity along the global y-direction at the 4th user-requested location (location is specified in the global coordinate system); 
SeaState['FVel5yi']           = False     # (m/s); fluid velocity along the global y-direction at the 5th user-requested location (location is specified in the global coordinate system); 
SeaState['FVel6yi']           = False     # (m/s); fluid velocity along the global y-direction at the 6th user-requested location (location is specified in the global coordinate system); 
SeaState['FVel7yi']           = False     # (m/s); fluid velocity along the global y-direction at the 7th user-requested location (location is specified in the global coordinate system); 
SeaState['FVel8yi']           = False     # (m/s); fluid velocity along the global y-direction at the 8th user-requested location (location is specified in the global coordinate system); 
SeaState['FVel9yi']           = False     # (m/s); fluid velocity along the global y-direction at the 9th user-requested location (location is specified in the global coordinate system); 
SeaState['FVel1zi']           = False     # (m/s); fluid velocity along the global z-direction at the 1st user-requested location (location is specified in the global coordinate system); 
SeaState['FVel2zi']           = False     # (m/s); fluid velocity along the global z-direction at the 2nd user-requested location (location is specified in the global coordinate system); 
SeaState['FVel3zi']           = False     # (m/s); fluid velocity along the global z-direction at the 3rd user-requested location (location is specified in the global coordinate system); 
SeaState['FVel4zi']           = False     # (m/s); fluid velocity along the global z-direction at the 4th user-requested location (location is specified in the global coordinate system); 
SeaState['FVel5zi']           = False     # (m/s); fluid velocity along the global z-direction at the 5th user-requested location (location is specified in the global coordinate system); 
SeaState['FVel6zi']           = False     # (m/s); fluid velocity along the global z-direction at the 6th user-requested location (location is specified in the global coordinate system); 
SeaState['FVel7zi']           = False     # (m/s); fluid velocity along the global z-direction at the 7th user-requested location (location is specified in the global coordinate system); 
SeaState['FVel8zi']           = False     # (m/s); fluid velocity along the global z-direction at the 8th user-requested location (location is specified in the global coordinate system); 
SeaState['FVel9zi']           = False     # (m/s); fluid velocity along the global z-direction at the 9th user-requested location (location is specified in the global coordinate system); 
SeaState['FAcc1xi']           = False     # (m/s^2); fluid acceleration along the global x-direction at the 1st user-requested location (location is specified in the global coordinate system); 
SeaState['FAcc2xi']           = False     # (m/s^2); fluid acceleration along the global x-direction at the 2nd user-requested location (location is specified in the global coordinate system); 
SeaState['FAcc3xi']           = False     # (m/s^2); fluid acceleration along the global x-direction at the 3rd user-requested location (location is specified in the global coordinate system); 
SeaState['FAcc4xi']           = False     # (m/s^2); fluid acceleration along the global x-direction at the 4th user-requested location (location is specified in the global coordinate system); 
SeaState['FAcc5xi']           = False     # (m/s^2); fluid acceleration along the global x-direction at the 5th user-requested location (location is specified in the global coordinate system); 
SeaState['FAcc6xi']           = False     # (m/s^2); fluid acceleration along the global x-direction at the 6th user-requested location (location is specified in the global coordinate system); 
SeaState['FAcc7xi']           = False     # (m/s^2); fluid acceleration along the global x-direction at the 7th user-requested location (location is specified in the global coordinate system); 
SeaState['FAcc8xi']           = False     # (m/s^2); fluid acceleration along the global x-direction at the 8th user-requested location (location is specified in the global coordinate system); 
SeaState['FAcc9xi']           = False     # (m/s^2); fluid acceleration along the global x-direction at the 9th user-requested location (location is specified in the global coordinate system); 
SeaState['FAcc1yi']           = False     # (m/s^2); fluid acceleration along the global y-direction at the 1st user-requested location (location is specified in the global coordinate system); 
SeaState['FAcc2yi']           = False     # (m/s^2); fluid acceleration along the global y-direction at the 2nd user-requested location (location is specified in the global coordinate system); 
SeaState['FAcc3yi']           = False     # (m/s^2); fluid acceleration along the global y-direction at the 3rd user-requested location (location is specified in the global coordinate system); 
SeaState['FAcc4yi']           = False     # (m/s^2); fluid acceleration along the global y-direction at the 4th user-requested location (location is specified in the global coordinate system); 
SeaState['FAcc5yi']           = False     # (m/s^2); fluid acceleration along the global y-direction at the 5th user-requested location (location is specified in the global coordinate system); 
SeaState['FAcc6yi']           = False     # (m/s^2); fluid acceleration along the global y-direction at the 6th user-requested location (location is specified in the global coordinate system); 
SeaState['FAcc7yi']           = False     # (m/s^2); fluid acceleration along the global y-direction at the 7th user-requested location (location is specified in the global coordinate system); 
SeaState['FAcc8yi']           = False     # (m/s^2); fluid acceleration along the global y-direction at the 8th user-requested location (location is specified in the global coordinate system); 
SeaState['FAcc9yi']           = False     # (m/s^2); fluid acceleration along the global y-direction at the 9th user-requested location (location is specified in the global coordinate system); 
SeaState['FAcc1zi']           = False     # (m/s^2); fluid acceleration along the global z-direction at the 1st user-requested location (location is specified in the global coordinate system); 
SeaState['FAcc2zi']           = False     # (m/s^2); fluid acceleration along the global z-direction at the 2nd user-requested location (location is specified in the global coordinate system); 
SeaState['FAcc3zi']           = False     # (m/s^2); fluid acceleration along the global z-direction at the 3rd user-requested location (location is specified in the global coordinate system); 
SeaState['FAcc4zi']           = False     # (m/s^2); fluid acceleration along the global z-direction at the 4th user-requested location (location is specified in the global coordinate system); 
SeaState['FAcc5zi']           = False     # (m/s^2); fluid acceleration along the global z-direction at the 5th user-requested location (location is specified in the global coordinate system); 
SeaState['FAcc6zi']           = False     # (m/s^2); fluid acceleration along the global z-direction at the 6th user-requested location (location is specified in the global coordinate system); 
SeaState['FAcc7zi']           = False     # (m/s^2); fluid acceleration along the global z-direction at the 7th user-requested location (location is specified in the global coordinate system); 
SeaState['FAcc8zi']           = False     # (m/s^2); fluid acceleration along the global z-direction at the 8th user-requested location (location is specified in the global coordinate system); 
SeaState['FAcc9zi']           = False     # (m/s^2); fluid acceleration along the global z-direction at the 9th user-requested location (location is specified in the global coordinate system); 
SeaState['FDynP1']            = False     # (Pa); fluid dynamic pressure at the 1st user-requested location (location is specified in the global coordinate system); 
SeaState['FDynP2']            = False     # (Pa); fluid dynamic pressure at the 2nd user-requested location (location is specified in the global coordinate system); 
SeaState['FDynP3']            = False     # (Pa); fluid dynamic pressure at the 3rd user-requested location (location is specified in the global coordinate system); 
SeaState['FDynP4']            = False     # (Pa); fluid dynamic pressure at the 4th user-requested location (location is specified in the global coordinate system); 
SeaState['FDynP5']            = False     # (Pa); fluid dynamic pressure at the 5th user-requested location (location is specified in the global coordinate system); 
SeaState['FDynP6']            = False     # (Pa); fluid dynamic pressure at the 6th user-requested location (location is specified in the global coordinate system); 
SeaState['FDynP7']            = False     # (Pa); fluid dynamic pressure at the 7th user-requested location (location is specified in the global coordinate system); 
SeaState['FDynP8']            = False     # (Pa); fluid dynamic pressure at the 8th user-requested location (location is specified in the global coordinate system); 
SeaState['FDynP9']            = False     # (Pa); fluid dynamic pressure at the 9th user-requested location (location is specified in the global coordinate system); 
SeaState['FAccMCF1xi']        = False     # (m/s^2); fluid acceleration with MCF approximation; 
SeaState['FAccMCF2xi']        = False     # (m/s^2); fluid acceleration with MCF approximation; 
SeaState['FAccMCF3xi']        = False     # (m/s^2); fluid acceleration with MCF approximation; 
SeaState['FAccMCF4xi']        = False     # (m/s^2); fluid acceleration with MCF approximation; 
SeaState['FAccMCF5xi']        = False     # (m/s^2); fluid acceleration with MCF approximation; 
SeaState['FAccMCF6xi']        = False     # (m/s^2); fluid acceleration with MCF approximation; 
SeaState['FAccMCF7xi']        = False     # (m/s^2); fluid acceleration with MCF approximation; 
SeaState['FAccMCF8xi']        = False     # (m/s^2); fluid acceleration with MCF approximation; 
SeaState['FAccMCF9xi']        = False     # (m/s^2); fluid acceleration with MCF approximation; 
SeaState['FAccMCF1yi']        = False     # (m/s^2); fluid acceleration with MCF approximation; 
SeaState['FAccMCF2yi']        = False     # (m/s^2); fluid acceleration with MCF approximation; 
SeaState['FAccMCF3yi']        = False     # (m/s^2); fluid acceleration with MCF approximation; 
SeaState['FAccMCF4yi']        = False     # (m/s^2); fluid acceleration with MCF approximation; 
SeaState['FAccMCF5yi']        = False     # (m/s^2); fluid acceleration with MCF approximation; 
SeaState['FAccMCF6yi']        = False     # (m/s^2); fluid acceleration with MCF approximation; 
SeaState['FAccMCF7yi']        = False     # (m/s^2); fluid acceleration with MCF approximation; 
SeaState['FAccMCF8yi']        = False     # (m/s^2); fluid acceleration with MCF approximation; 
SeaState['FAccMCF9yi']        = False     # (m/s^2); fluid acceleration with MCF approximation; 
SeaState['FAccMCF1zi']        = False     # (m/s^2); fluid acceleration with MCF approximation; 
SeaState['FAccMCF2zi']        = False     # (m/s^2); fluid acceleration with MCF approximation; 
SeaState['FAccMCF3zi']        = False     # (m/s^2); fluid acceleration with MCF approximation; 
SeaState['FAccMCF4zi']        = False     # (m/s^2); fluid acceleration with MCF approximation; 
SeaState['FAccMCF5zi']        = False     # (m/s^2); fluid acceleration with MCF approximation; 
SeaState['FAccMCF6zi']        = False     # (m/s^2); fluid acceleration with MCF approximation; 
SeaState['FAccMCF7zi']        = False     # (m/s^2); fluid acceleration with MCF approximation; 
SeaState['FAccMCF8zi']        = False     # (m/s^2); fluid acceleration with MCF approximation; 
SeaState['FAccMCF9zi']        = False     # (m/s^2); fluid acceleration with MCF approximation; 


""" SubDyn """
SubDyn = {}

# Member Forces (MxxNxChannelName)
SubDyn['FKxe']                = False     # (N); ; 
SubDyn['FKye']                = False     # (N); ; 
SubDyn['FKze']                = False     # (N); ; 
SubDyn['FMxe']                = False     # (N); ; 
SubDyn['FMye']                = False     # (N); ; 
SubDyn['FMze']                = False     # (N); ; 
SubDyn['MKxe']                = False     # (N*m); ; 
SubDyn['MKye']                = False     # (N*m); ; 
SubDyn['MKze']                = False     # (N*m); ; 
SubDyn['MMxe']                = False     # (N*m); ; 
SubDyn['MMye']                = False     # (N*m); ; 
SubDyn['MMze']                = False     # (N*m); ; 

# Displacements (MxxNxChannelName)
SubDyn['TDxss']               = False     # (m); ; 
SubDyn['TDyss']               = False     # (m); ; 
SubDyn['TDzss']               = False     # (m); ; 
SubDyn['RDxe']                = False     # (rad); ; 
SubDyn['RDye']                = False     # (rad); ; 
SubDyn['RDze']                = False     # (rad); ; 

# Accelerations (MxxNxChannelName)
SubDyn['TAxe']                = False     # (m/s^2); ; 
SubDyn['TAye']                = False     # (m/s^2); ; 
SubDyn['TAze']                = False     # (m/s^2); ; 
SubDyn['RAxe']                = False     # (rad/s^2); ; 
SubDyn['RAye']                = False     # (rad/s^2); ; 
SubDyn['RAze']                = False     # (rad/s^2); ; 

# Reactions
SubDyn['ReactFXss']           = False     # (N); ; 
SubDyn['ReactFYss']           = False     # (N); ; 
SubDyn['ReactFZss']           = False     # (N); ; 
SubDyn['ReactMXss']           = False     # (N*m); ; 
SubDyn['ReactMYss']           = False     # (N*m); ; 
SubDyn['ReactMZss']           = False     # (N*m); ; 
SubDyn['IntfFXss']            = False     # (N); ; 
SubDyn['IntfFYss']            = False     # (N); ; 
SubDyn['IntfFZss']            = False     # (N); ; 
SubDyn['IntfMXss']            = False     # (N*m); ; 
SubDyn['IntfMYss']            = False     # (N*m); ; 
SubDyn['IntfMZss']            = False     # (N*m); ; 

# Interface Deflections
SubDyn['IntfTDXss']           = False     # (m); ; 
SubDyn['IntfTDYss']           = False     # (m); ; 
SubDyn['IntfTDZss']           = False     # (m); ; 
SubDyn['IntfRDXss']           = False     # (rad); ; 
SubDyn['IntfRDYss']           = False     # (rad); ; 
SubDyn['IntfRDZss']           = False     # (rad); ; 

# Interface Accelerations
SubDyn['IntfTAXss']           = False     # (m/s^2); ; 
SubDyn['IntfTAYss']           = False     # (m/s^2); ; 
SubDyn['IntfTAZss']           = False     # (m/s^2); ; 
SubDyn['IntfRAXss']           = False     # (rad/s^2); ; 
SubDyn['IntfRAYss']           = False     # (rad/s^2); ; 
SubDyn['IntfRAZss']           = False     # (rad/s^2); ; 

# Modal Parameters (NameXX for mode number XX)
SubDyn['SSqm']                = False     # (-); ; 
SubDyn['SSqmd']               = False     # (1/s); ; 
SubDyn['SSqmdd']              = False     # (1/s^2); ; 

""" WAMIT """
WAMIT = {}

# WAMIT Body Forces
WAMIT['Wave1El2']             = False     # (m); 2nd order wave elevation correction; 
WAMIT['Wave2El2']             = False     # (m); 2nd order wave elevation correction; 
WAMIT['Wave3El2']             = False     # (m); 2nd order wave elevation correction; 
WAMIT['Wave4El2']             = False     # (m); 2nd order wave elevation correction; 
WAMIT['Wave5El2']             = False     # (m); 2nd order wave elevation correction; 
WAMIT['Wave6El2']             = False     # (m); 2nd order wave elevation correction; 
WAMIT['Wave7El2']             = False     # (m); 2nd order wave elevation correction; 
WAMIT['Wave8El2']             = False     # (m); 2nd order wave elevation correction; 
WAMIT['Wave9El2']             = False     # (m); 2nd order wave elevation correction; 

# WAMIT second order Body Forces
WAMIT['WavesF2xi']            = False     # (N); ; 
WAMIT['WavesF2yi']            = False     # (N); ; 
WAMIT['WavesF2zi']            = False     # (N); ; 
WAMIT['WavesM2xi']            = False     # (N m); ; 
WAMIT['WavesM2yi']            = False     # (N m); ; 
WAMIT['WavesM2zi']            = False     # (N m); ; 

# WAMIT Body Forces
WAMIT['WavesFxi']             = False     # (N); ; 
WAMIT['WavesFyi']             = False     # (N); ; 
WAMIT['WavesFzi']             = False     # (N); ; 
WAMIT['WavesMxi']             = False     # (N m); ; 
WAMIT['WavesMyi']             = False     # (N m); ; 
WAMIT['WavesMzi']             = False     # (N m); ; 
WAMIT['HdrStcFxi']            = False     # (N); ; 
WAMIT['HdrStcFyi']            = False     # (N); ; 
WAMIT['HdrStcFzi']            = False     # (N); ; 
WAMIT['HdrStcMxi']            = False     # (N m); ; 
WAMIT['HdrStcMyi']            = False     # (N m); ; 
WAMIT['HdrStcMzi']            = False     # (N m); ; 
WAMIT['RdtnFxi']              = False     # (N); ; 
WAMIT['RdtnFyi']              = False     # (N); ; 
WAMIT['RdtnFzi']              = False     # (N); ; 
WAMIT['RdtnMxi']              = False     # (N m); ; 
WAMIT['RdtnMyi']              = False     # (N m); ; 
WAMIT['RdtnMzi']              = False     # (N m); ; 

""" AeroDyn_Nodes """
AeroDyn_Nodes = {}

# Blade
AeroDyn_Nodes['VUndx']        = False     # (m/s); (will be deprecated) x-component of undisturbed wind velocity at each node; ill-defined / implementation specific
AeroDyn_Nodes['VUndy']        = False     # (m/s); (will be deprecated) y-component of undisturbed wind velocity at each node; ill-defined / implementation specific
AeroDyn_Nodes['VUndz']        = False     # (m/s); (will be deprecated) z-component of undisturbed wind velocity at each node; ill-defined / implementation specific
AeroDyn_Nodes['VUndxi']       = False     # (m/s); x-component of undisturbed wind velocity at each node; inertial/global coordinate system
AeroDyn_Nodes['VUndyi']       = False     # (m/s); y-component of undisturbed wind velocity at each node; inertial/global coordinate system
AeroDyn_Nodes['VUndzi']       = False     # (m/s); z-component of undisturbed wind velocity at each node; inertial/global coordinate system
AeroDyn_Nodes['VUndxp']       = False     # (m/s); x-component of undisturbed wind velocity at each node; polar coordinate system
AeroDyn_Nodes['VUndyp']       = False     # (m/s); y-component of undisturbed wind velocity at each node; polar coordinate system
AeroDyn_Nodes['VUndzp']       = False     # (m/s); z-component of undisturbed wind velocity at each node; polar coordinate system
AeroDyn_Nodes['VUndxl']       = False     # (m/s); x-component of undisturbed wind velocity at each node; local-polar coordinate system
AeroDyn_Nodes['VUndyl']       = False     # (m/s); y-component of undisturbed wind velocity at each node; local-polar coordinate system
AeroDyn_Nodes['VUndzl']       = False     # (m/s); z-component of undisturbed wind velocity at each node; local-polar coordinate system
AeroDyn_Nodes['VUndxa']       = False     # (m/s); x-component of undisturbed wind velocity at each node; airfoil coordinate system
AeroDyn_Nodes['VUndya']       = False     # (m/s); y-component of undisturbed wind velocity at each node; airfoil coordinate system
AeroDyn_Nodes['VUndza']       = False     # (m/s); z-component of undisturbed wind velocity at each node; airfoil coordinate system
AeroDyn_Nodes['VDisx']        = False     # (m/s); (will be deprecated) x-component of disturbed wind velocity at each node; ill-defined / implementation specific
AeroDyn_Nodes['VDisy']        = False     # (m/s); (will be deprecated) y-component of disturbed wind velocity at each node; ill-defined / implementation specific
AeroDyn_Nodes['VDisz']        = False     # (m/s); (will be deprecated) z-component of disturbed wind velocity at each node; ill-defined / implementation specific
AeroDyn_Nodes['VDisxi']       = False     # (m/s); x-component of disturbed wind velocity at each node; inertial/global coordinate system
AeroDyn_Nodes['VDisyi']       = False     # (m/s); y-component of disturbed wind velocity at each node; inertial/global coordinate system
AeroDyn_Nodes['VDiszi']       = False     # (m/s); z-component of disturbed wind velocity at each node; inertial/global coordinate system
AeroDyn_Nodes['VDisxp']       = False     # (m/s); x-component of disturbed wind velocity at each node; polar coordinate system
AeroDyn_Nodes['VDisyp']       = False     # (m/s); y-component of disturbed wind velocity at each node; polar coordinate system
AeroDyn_Nodes['VDiszp']       = False     # (m/s); z-component of disturbed wind velocity at each node; polar coordinate system
AeroDyn_Nodes['VDisxl']       = False     # (m/s); x-component of disturbed wind velocity at each node; local-polar coordinate system
AeroDyn_Nodes['VDisyl']       = False     # (m/s); y-component of disturbed wind velocity at each node; local-polar coordinate system
AeroDyn_Nodes['VDiszl']       = False     # (m/s); z-component of disturbed wind velocity at each node; local-polar coordinate system
AeroDyn_Nodes['VDisxa']       = False     # (m/s); x-component of disturbed wind velocity at each node; airfoil coordinate system
AeroDyn_Nodes['VDisya']       = False     # (m/s); y-component of disturbed wind velocity at each node; airfoil coordinate system
AeroDyn_Nodes['VDisza']       = False     # (m/s); z-component of disturbed wind velocity at each node; airfoil coordinate system
AeroDyn_Nodes['STVx']         = False     # (m/s); (will be deprecated) x-component of structural translational velocity at each node; ill-defined / implementation specific
AeroDyn_Nodes['STVy']         = False     # (m/s); (will be deprecated) y-component of structural translational velocity at each node; ill-defined / implementation specific
AeroDyn_Nodes['STVz']         = False     # (m/s); (will be deprecated) z-component of structural translational velocity at each node; ill-defined / implementation specific
AeroDyn_Nodes['STVxi']        = False     # (m/s); x-component of structural translational velocity at each node; inertial/global coordinate system
AeroDyn_Nodes['STVyi']        = False     # (m/s); y-component of structural translational velocity at each node; inertial/global coordinate system
AeroDyn_Nodes['STVzi']        = False     # (m/s); z-component of structural translational velocity at each node; inertial/global coordinate system
AeroDyn_Nodes['STVxp']        = False     # (m/s); x-component of structural translational velocity at each node; polar coordinate system
AeroDyn_Nodes['STVyp']        = False     # (m/s); y-component of structural translational velocity at each node; polar coordinate system
AeroDyn_Nodes['STVzp']        = False     # (m/s); z-component of structural translational velocity at each node; polar coordinate system
AeroDyn_Nodes['STVxl']        = False     # (m/s); x-component of structural translational velocity at each node; local-polar coordinate system
AeroDyn_Nodes['STVyl']        = False     # (m/s); y-component of structural translational velocity at each node; local-polar coordinate system
AeroDyn_Nodes['STVzl']        = False     # (m/s); z-component of structural translational velocity at each node; local-polar coordinate system
AeroDyn_Nodes['STVxa']        = False     # (m/s); x-component of structural translational velocity at each node; airfoil coordinate system
AeroDyn_Nodes['STVya']        = False     # (m/s); y-component of structural translational velocity at each node; airfoil coordinate system
AeroDyn_Nodes['STVza']        = False     # (m/s); z-component of structural translational velocity at each node; airfoil coordinate system
AeroDyn_Nodes['Vindx']        = False     # (m/s); (will be deprecated) Axial induced wind velocity at each node; local blade coordinate system
AeroDyn_Nodes['Vindy']        = False     # (m/s); (will be deprecated) Tangential induced wind velocity at each node; local blade coordinate system
AeroDyn_Nodes['Vindxi']       = False     # (m/s); x-component of induced velocity at each node ; inertial/global coordinate system
AeroDyn_Nodes['Vindyi']       = False     # (m/s); y-component of induced velocity at each node; inertial/global coordinate system
AeroDyn_Nodes['Vindzi']       = False     # (m/s); z-component of induced velocity at each node; inertial/global coordinate system
AeroDyn_Nodes['Vindxp']       = False     # (m/s); x-component of induced velocity at each node ; polar coordinate system
AeroDyn_Nodes['Uin']          = False     # (m/s); x-component of induced velocity at each node ; polar coordinate system
AeroDyn_Nodes['Vindyp']       = False     # (m/s); y-component of induced velocity at each node; polar coordinate system
AeroDyn_Nodes['Uit']          = False     # (m/s); y-component of induced velocity at each node; polar coordinate system
AeroDyn_Nodes['Vindzp']       = False     # (m/s); z-component of induced velocity at each node; polar coordinate system
AeroDyn_Nodes['Uir']          = False     # (m/s); z-component of induced velocity at each node; polar coordinate system
AeroDyn_Nodes['Vindxl']       = False     # (m/s); x-component of induced velocity at each node ; local-polar coordinate system
AeroDyn_Nodes['Vindyl']       = False     # (m/s); y-component of induced velocity at each node; local-polar coordinate system
AeroDyn_Nodes['Vindzl']       = False     # (m/s); z-component of induced velocity at each node; local-polar coordinate system
AeroDyn_Nodes['Vindxa']       = False     # (m/s); x-component of induced velocity at each node ; airfoil coordinate system
AeroDyn_Nodes['Vindya']       = False     # (m/s); y-component of induced velocity at each node; airfoil coordinate system
AeroDyn_Nodes['Vindza']       = False     # (m/s); z-component of induced velocity at each node; airfoil coordinate system
AeroDyn_Nodes['Vx']           = False     # (m/s); (will be deprecated) Local axial velocity (VDisx - STVx); ill-defined / implementation specific
AeroDyn_Nodes['Vy']           = False     # (m/s); (will be deprecated) Local tangential velocity  (VDisy - STVy); ill-defined / implementation specific
AeroDyn_Nodes['VRel']         = False     # (m/s); Relative wind speed at each node, computed using x-y components in the airfoil system; in xa-ya plane, airfoil coordinate system
AeroDyn_Nodes['DynP']         = False     # (Pa); Dynamic pressure at each node; in xa-ya plane, airfoil coordinate system
AeroDyn_Nodes['Re']           = False     # (-); Reynolds number (in millions) at each node; in xa-ya plane, airfoil coordinate system
AeroDyn_Nodes['M']            = False     # (-); Mach number at each node; in xa-ya plane, airfoil coordinate system
AeroDyn_Nodes['AxInd']        = False     # (-); Axial induction factor at each node; implementation specific
AeroDyn_Nodes['TnInd']        = False     # (-); Tangential induction factor at each node; implementation specific
AeroDyn_Nodes['AxInd_qs']     = False     # (-); Quasi-steady axial induction factor as computed within the quasi-steady BEM algorithm (before DBEMT and skew correction); implementation specific
AeroDyn_Nodes['TnInd_qs']     = False     # (-); Quasi-steady tangential induction factor as computed within the quasi-steady BEM algorithm (before DBEMT and skew correction); implementation specific
AeroDyn_Nodes['Alpha']        = False     # (deg); Angle of attack at each node; airfoil coordinate system
AeroDyn_Nodes['Phi']          = False     # (deg); Inflow angle at each node; ill-defined / implementation specific
AeroDyn_Nodes['Theta']        = False     # (deg); Pitch+Twist angle at each node; 
AeroDyn_Nodes['Curve']        = False     # (deg); Curvature angle at each node; 
AeroDyn_Nodes['Toe']          = False     # (deg); Toe angle at each node; 
AeroDyn_Nodes['Cl']           = False     # (-); Lift force coefficient at each node, including unsteady effects; in xa-ya plane, airfoil coordinate system
AeroDyn_Nodes['Cd']           = False     # (-); Drag force coefficient at each node, including unsteady effects; in xa-ya plane, airfoil coordinate system
AeroDyn_Nodes['Cm']           = False     # (-); Pitching moment coefficient at each node, including unsteady effects; about za, airfoil coordinate system
AeroDyn_Nodes['Cma']          = False     # (-); Pitching moment coefficient at each node, including unsteady effects; about za, airfoil coordinate system
AeroDyn_Nodes['Cx']           = False     # (-); (will be deprecated) Normal force (to plane) coefficient at each node; ill-defined / implementation specific
AeroDyn_Nodes['Cy']           = False     # (-); (will be deprecated) Tangential force (to plane) coefficient at each node; ill-defined / implementation specific
AeroDyn_Nodes['Cn']           = False     # (-); Normal force (to chord) coefficient at each node; airfoil coordinate system
AeroDyn_Nodes['Cxa']          = False     # (-); Normal force (to chord) coefficient at each node; airfoil coordinate system
AeroDyn_Nodes['Ct']           = False     # (-); Tangential force (to chord) coefficient at each node - Negative along ya!; airfoil coordinate system
AeroDyn_Nodes['Fxi']          = False     # (N/m); Force per unit length in the x direction; inertial/global coordinate system
AeroDyn_Nodes['Fyi']          = False     # (N/m); Force per unit length in the y direction; inertial/global coordinate system
AeroDyn_Nodes['Fzi']          = False     # (N/m); Force per unit length in the z direction; inertial/global coordinate system
AeroDyn_Nodes['Mxi']          = False     # (N-m/m); Moment per unit length in the x direction; inertial/global coordinate system
AeroDyn_Nodes['Myi']          = False     # (N-m/m); Moment per unit length in the y direction; inertial/global coordinate system
AeroDyn_Nodes['Mzi']          = False     # (N-m/m); Moment per unit length in the z direction; inertial/global coordinate system
AeroDyn_Nodes['Fxp']          = False     # (N/m); Force per unit length in the x direction; polar coordinate system
AeroDyn_Nodes['Fyp']          = False     # (N/m); Force per unit length in the y direction; polar coordinate system
AeroDyn_Nodes['Fzp']          = False     # (N/m); Force per unit length in the z direction; polar coordinate system
AeroDyn_Nodes['Mxp']          = False     # (N-m/m); Moment per unit length in the x direction; polar coordinate system
AeroDyn_Nodes['Myp']          = False     # (N-m/m); Moment per unit length in the y direction; polar coordinate system
AeroDyn_Nodes['Mzp']          = False     # (N-m/m); Moment per unit length in the z direction; polar coordinate system
AeroDyn_Nodes['Fxl']          = False     # (N/m); Force per unit length in the x direction; local-polar coordinate system
AeroDyn_Nodes['Fyl']          = False     # (N/m); Force per unit length in the y direction; local-polar coordinate system
AeroDyn_Nodes['Fzl']          = False     # (N/m); Force per unit length in the z direction; local-polar coordinate system
AeroDyn_Nodes['Mxl']          = False     # (N-m/m); Moment per unit length in the x direction; local-polar coordinate system
AeroDyn_Nodes['Myl']          = False     # (N-m/m); Moment per unit length in the y direction; local-polar coordinate system
AeroDyn_Nodes['Mzl']          = False     # (N-m/m); Moment per unit length in the z direction; local-polar coordinate system
AeroDyn_Nodes['Fl']           = False     # (N/m); Lift force per unit length at each node; in xa-ya plane, airfoil coordinate system
AeroDyn_Nodes['Fd']           = False     # (N/m); Drag force per unit length at each node; in xa-ya plane, airfoil coordinate system
AeroDyn_Nodes['Mm']           = False     # (N-m/m); Pitching moment per unit length at each node; about za, airfoil coordinate system
AeroDyn_Nodes['Mza']          = False     # (N-m/m); Pitching moment per unit length at each node; about za, airfoil coordinate system
AeroDyn_Nodes['Fx']           = False     # (N/m); (will be deprecated) Normal force (to plane) per unit length at each node; ill-defined / implementation specific
AeroDyn_Nodes['Fy']           = False     # (N/m); (will be deprecated) Tangential force (to plane) per unit length at each node; ill-defined / implementation specific
AeroDyn_Nodes['Fn']           = False     # (N/m); Normal force (to chord) per unit length at each node; airfoil coordinate system
AeroDyn_Nodes['Fxa']          = False     # (N/m); Normal force (to chord) per unit length at each node; airfoil coordinate system
AeroDyn_Nodes['Ft']           = False     # (N/m); Tangential force (to chord) per unit length at each node - Negative along ya!; airfoil coordinate system
AeroDyn_Nodes['Gam']          = False     # (m^2/s); Gamma -- circulation on blade; about za, airfoil coordinate system
AeroDyn_Nodes['Clrnc']        = False     # (m); Tower clearance at each node (based on the absolute distance to the nearest point in the tower from blade node B#N# minus the local tower radius, in the deflected configuration); please note that this clearance is only approximate because the calculation assumes that the blade is a line with no volume (however, the calculation does use the local tower radius); when blade node B#N# is above the tower top (or below the tower base), the absolute distance to the tower top (or base) minus the local tower radius, in the deflected configuration, is output; 
AeroDyn_Nodes['GeomPhi']      = False     # (1/0); Geometric phi? If phi was solved using normal BEMT equations, GeomPhi = 1; otherwise, if it was solved geometrically, GeomPhi = 0.; 
AeroDyn_Nodes['Chi']          = False     # (deg); Skew angle (used in skewed wake correction); 
AeroDyn_Nodes['UA_Flag']      = False     # (-); Flag indicating if UA is turned on for this node.; 
AeroDyn_Nodes['UA_x1']        = False     # (rad); time-history of wake vorticity contributing to effective angle of attack; 
AeroDyn_Nodes['UA_x2']        = False     # (rad); time-history of wake vorticity contributing to effective angle of attack; 
AeroDyn_Nodes['UA_x3']        = False     # (-); dimension of cl (UAMod4) or cn (UAMod5); lagging the fully-attached coefficient; 
AeroDyn_Nodes['UA_x4']        = False     # (-); UAMod4 and 5 separation factor; 
AeroDyn_Nodes['UA_x5']        = False     # (-); UAMod5 vortex term; 
AeroDyn_Nodes['Debug1']       = False     # (-); Placeholders for debugging channels; 
AeroDyn_Nodes['Debug2']       = False     # (-); Placeholders for debugging channels; 
AeroDyn_Nodes['Debug3']       = False     # (-); Placeholders for debugging channels; 
AeroDyn_Nodes['CpMin']        = False     # (-); Pressure coefficient; 
AeroDyn_Nodes['SgCav']        = False     # (-); Cavitation number; 
AeroDyn_Nodes['SigCr']        = False     # (-); Critical cavitation number; 
AeroDyn_Nodes['BEM_F_qs']     = False     # (-); Tip/hub loss factor in quasi-steady BEM algorithm; 
AeroDyn_Nodes['BEM_k_qs']     = False     # (-); k factor in quasi-steady BEM algorithm; 
AeroDyn_Nodes['BEM_kp_qs']    = False     # (-); kp factor in quasi-steady BEM algorithm; 
AeroDyn_Nodes['BEM_CT_qs']    = False     # (-); Quasi-steady thrust coefficient as computed by the quasi-steady BEM algorithm. ; 
AeroDyn_Nodes['Cl_qs']        = False     # (-); Static portion of lift force coefficient at each node, without  unsteady effects; in xa-ya plane, airfoil coordinate system
AeroDyn_Nodes['Cd_qs']        = False     # (-); Static portion of drag force coefficient at each node, without unsteady effects; in xa-ya plane, airfoil coordinate system
AeroDyn_Nodes['Cm_qs']        = False     # (-); Static portion of pitching moment coefficient at each node, without unsteady effects; about za, airfoil coordinate system
AeroDyn_Nodes['Fbxi']         = False     # (N/m); Buoyancy force per unit length in the x direction; inertial/global coordinate system
AeroDyn_Nodes['Fbyi']         = False     # (N/m); Buoyancy force per unit length in the y direction; inertial/global coordinate system
AeroDyn_Nodes['Fbzi']         = False     # (N/m); Buoyancy force per unit length in the z direction; inertial/global coordinate system
AeroDyn_Nodes['Mbxi']         = False     # (N-m/m); Buoyancy moment per unit length in the x direction; inertial/global coordinate system
AeroDyn_Nodes['Mbyi']         = False     # (N-m/m); Buoyancy moment per unit length in the y direction; inertial/global coordinate system
AeroDyn_Nodes['Mbzi']         = False     # (N-m/m); Buoyancy moment per unit length in the z direction; inertial/global coordinate system
AeroDyn_Nodes['Fbxp']         = False     # (N/m); Buoyancy force per unit length in the x direction; polar coordinate system
AeroDyn_Nodes['Fbyp']         = False     # (N/m); Buoyancy force per unit length in the y direction; polar coordinate system
AeroDyn_Nodes['Fbzp']         = False     # (N/m); Buoyancy force per unit length in the z direction; polar coordinate system
AeroDyn_Nodes['Mbxp']         = False     # (N-m/m); Buoyancy moment per unit length in the x direction; polar coordinate system
AeroDyn_Nodes['Mbyp']         = False     # (N-m/m); Buoyancy moment per unit length in the y direction; polar coordinate system
AeroDyn_Nodes['Mbzp']         = False     # (N-m/m); Buoyancy moment per unit length in the z direction; polar coordinate system
AeroDyn_Nodes['Fbxl']         = False     # (N/m); Buoyancy force per unit length in the x direction; local-polar coordinate system
AeroDyn_Nodes['Fbyl']         = False     # (N/m); Buoyancy force per unit length in the y direction; local-polar coordinate system
AeroDyn_Nodes['Fbzl']         = False     # (N/m); Buoyancy force per unit length in the z direction; local-polar coordinate system
AeroDyn_Nodes['Mbxl']         = False     # (N-m/m); Buoyancy moment per unit length in the x direction; local-polar coordinate system
AeroDyn_Nodes['Mbyl']         = False     # (N-m/m); Buoyancy moment per unit length in the y direction; local-polar coordinate system
AeroDyn_Nodes['Mbzl']         = False     # (N-m/m); Buoyancy moment per unit length in the z direction; local-polar coordinate system
AeroDyn_Nodes['Fbxa']         = False     # (N/m); Buoyancy force per unit length in the x direction; airfoil coordinate system
AeroDyn_Nodes['Fbn']          = False     # (N/m); Buoyancy force per unit length in the x direction; airfoil coordinate system
AeroDyn_Nodes['Fbya']         = False     # (N/m); Buoyancy force per unit length in the y direction; airfoil coordinate system
AeroDyn_Nodes['Fbt']          = False     # (N/m); Buoyancy force per unit length in the y direction; airfoil coordinate system
AeroDyn_Nodes['Fbza']         = False     # (N/m); Buoyancy force per unit length in the z direction; airfoil coordinate system
AeroDyn_Nodes['Fbs']          = False     # (N/m); Buoyancy force per unit length in the z direction; airfoil coordinate system
AeroDyn_Nodes['Mbxa']         = False     # (N-m/m); Buoyancy moment per unit length in the x direction; airfoil coordinate system
AeroDyn_Nodes['Mbn']          = False     # (N-m/m); Buoyancy moment per unit length in the x direction; airfoil coordinate system
AeroDyn_Nodes['Mbya']         = False     # (N-m/m); Buoyancy moment per unit length in the y direction; airfoil coordinate system
AeroDyn_Nodes['Mbt']          = False     # (N-m/m); Buoyancy moment per unit length in the y direction; airfoil coordinate system
AeroDyn_Nodes['Mbza']         = False     # (N-m/m); Buoyancy moment per unit length in the z direction; airfoil coordinate system
AeroDyn_Nodes['Mbs']          = False     # (N-m/m); Buoyancy moment per unit length in the z direction; airfoil coordinate system


""" BeamDyn_Nodes """
BeamDyn_Nodes = {}

# Sectional Loads
BeamDyn_Nodes['FxL']          = False     # (N); Sectional force resultants at each node expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['FyL']          = False     # (N); Sectional force resultants at each node expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['FzL']          = False     # (N); Sectional force resultants at each node expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['MxL']          = False     # (N-m); Sectional moment resultants at each node expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['MyL']          = False     # (N-m); Sectional moment resultants at each node expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['MzL']          = False     # (N-m); Sectional moment resultants at each node expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['Fxr']          = False     # (N); Sectional force resultants at each node expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn_Nodes['Fyr']          = False     # (N); Sectional force resultants at each node expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn_Nodes['Fzr']          = False     # (N); Sectional force resultants at each node expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn_Nodes['Mxr']          = False     # (N-m); Sectional moment resultants at each node expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn_Nodes['Myr']          = False     # (N-m); Sectional moment resultants at each node expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn_Nodes['Mzr']          = False     # (N-m); Sectional moment resultants at each node expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system

# Sectional Motions
BeamDyn_Nodes['TDxr']         = False     # (m); Sectional translational deflection (relative to the undeflected position) at each node expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn_Nodes['TDyr']         = False     # (m); Sectional translational deflection (relative to the undeflected position) at each node expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn_Nodes['TDzr']         = False     # (m); Sectional translational deflection (relative to the undeflected position) at each node expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn_Nodes['RDxr']         = False     # (-); Sectional angular/rotational deflection Wiener-Milenkovic parameter (relative to the undeflected orientation) at each node expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn_Nodes['RDyr']         = False     # (-); Sectional angular/rotational deflection Wiener-Milenkovic parameter (relative to the undeflected orientation) at each node expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn_Nodes['RDzr']         = False     # (-); Sectional angular/rotational deflection Wiener-Milenkovic parameter (relative to the undeflected orientation) at each node expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system
BeamDyn_Nodes['AbsXg']        = False     # (m); Node position in X (global coordinate) ; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system 
BeamDyn_Nodes['AbsYg']        = False     # (m); Node position in Y (global coordinate) ; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system 
BeamDyn_Nodes['AbsZg']        = False     # (m); Node position in Z (global coordinate) ; g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system 
BeamDyn_Nodes['AbsXr']        = False     # (m); Node position in X (relative to root) ; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system 
BeamDyn_Nodes['AbsYr']        = False     # (m); Node position in Y (relative to root) ; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system 
BeamDyn_Nodes['AbsZr']        = False     # (m); Node position in Z (relative to root) ; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system 
BeamDyn_Nodes['TVxg']         = False     # (m/s); Sectional translational velocities (absolute); g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system 
BeamDyn_Nodes['TVyg']         = False     # (m/s); Sectional translational velocities (absolute); g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system 
BeamDyn_Nodes['TVzg']         = False     # (m/s); Sectional translational velocities (absolute); g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system 
BeamDyn_Nodes['TVxl']         = False     # (m/s); Sectional translational velocities (absolute); l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['TVyl']         = False     # (m/s); Sectional translational velocities (absolute); l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['TVzl']         = False     # (m/s); Sectional translational velocities (absolute); l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['TVxr']         = False     # (m/s); Sectional translational velocities (absolute); r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system 
BeamDyn_Nodes['TVyr']         = False     # (m/s); Sectional translational velocities (absolute); r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system 
BeamDyn_Nodes['TVzr']         = False     # (m/s); Sectional translational velocities (absolute); r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system 
BeamDyn_Nodes['RVxg']         = False     # (deg/s); Sectional angular/rotational velocities (absolute); g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system 
BeamDyn_Nodes['RVyg']         = False     # (deg/s); Sectional angular/rotational velocities (absolute); g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system 
BeamDyn_Nodes['RVzg']         = False     # (deg/s); Sectional angular/rotational velocities (absolute); g: the global inertial frame coordinate system; when coupled to FAST, this is equivalent to FAST s global inertial frame (i) coordinate system 
BeamDyn_Nodes['RVxl']         = False     # (deg/s); Sectional angular/rotational velocities (absolute); l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['RVyl']         = False     # (deg/s); Sectional angular/rotational velocities (absolute); l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['RVzl']         = False     # (deg/s); Sectional angular/rotational velocities (absolute); l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['RVxr']         = False     # (deg/s); Sectional angular/rotational velocities (absolute); r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system 
BeamDyn_Nodes['RVyr']         = False     # (deg/s); Sectional angular/rotational velocities (absolute); r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system 
BeamDyn_Nodes['RVzr']         = False     # (deg/s); Sectional angular/rotational velocities (absolute); r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system 
BeamDyn_Nodes['TAxl']         = False     # (m/s^2); Sectional angular/rotational velocities (absolute); l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['TAyl']         = False     # (m/s^2); Sectional angular/rotational velocities (absolute); l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['TAzl']         = False     # (m/s^2); Sectional angular/rotational velocities (absolute); l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['TAxr']         = False     # (m/s^2); Sectional angular/rotational velocities (absolute); r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system 
BeamDyn_Nodes['TAyr']         = False     # (m/s^2); Sectional angular/rotational velocities (absolute); r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system 
BeamDyn_Nodes['TAzr']         = False     # (m/s^2); Sectional angular/rotational velocities (absolute); r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system 
BeamDyn_Nodes['RAxl']         = False     # (deg/s^2); Sectional angular/rotational velocities (absolute); l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['RAyl']         = False     # (deg/s^2); Sectional angular/rotational velocities (absolute); l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['RAzl']         = False     # (deg/s^2); Sectional angular/rotational velocities (absolute); l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['RAxr']         = False     # (deg/s^2); Sectional angular/rotational velocities (absolute); r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system 
BeamDyn_Nodes['RAyr']         = False     # (deg/s^2); Sectional angular/rotational velocities (absolute); r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system 
BeamDyn_Nodes['RAzr']         = False     # (deg/s^2); Sectional angular/rotational velocities (absolute); r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system 

# Applied Loads
BeamDyn_Nodes['PFxL']         = False     # (N); Applied point forces at each node expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['PFyL']         = False     # (N); Applied point forces at each node expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['PFzL']         = False     # (N); Applied point forces at each node expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['PMxL']         = False     # (N-m); Applied point moments at each node expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['PMyL']         = False     # (N-m); Applied point moments at each node expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['PMzL']         = False     # (N-m); Applied point moments at each node expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['DFxL']         = False     # (N/m); Applied distributed forces at each node expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['DFyL']         = False     # (N/m); Applied distributed forces at each node expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['DFzL']         = False     # (N/m); Applied distributed forces at each node expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['DMxL']         = False     # (N-m/m); Applied distributed moments at each node expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['DMyL']         = False     # (N-m/m); Applied distributed moments at each node expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['DMzL']         = False     # (N-m/m); Applied distributed moments at each node expressed in l; l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['DFxR']         = False     # (N/m); Applied distributed forces at each node expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system 
BeamDyn_Nodes['DFyR']         = False     # (N/m); Applied distributed forces at each node expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system 
BeamDyn_Nodes['DFzR']         = False     # (N/m); Applied distributed forces at each node expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system 
BeamDyn_Nodes['DMxR']         = False     # (N-m/m); Applied distributed forces at each node expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system 
BeamDyn_Nodes['DMyR']         = False     # (N-m/m); Applied distributed forces at each node expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system 
BeamDyn_Nodes['DMzR']         = False     # (N-m/m); Applied distributed forces at each node expressed in r; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system 

# Sectional Partial Loads (debugging)
BeamDyn_Nodes['FFbxl']        = False     # (N); Gyroscopic force x ; l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['FFbyl']        = False     # (N); Gyroscopic force y ; l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['FFbzl']        = False     # (N); Gyroscopic force z ; l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['FFbxr']        = False     # (N); Gyroscopic force x ; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system 
BeamDyn_Nodes['FFbyr']        = False     # (N); Gyroscopic force y ; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system 
BeamDyn_Nodes['FFbzr']        = False     # (N); Gyroscopic force z ; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system 
BeamDyn_Nodes['MFbxl']        = False     # (N-m); Gyroscopic moment about x ; l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['MFbyl']        = False     # (N-m); Gyroscopic moment about y ; l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['MFbzl']        = False     # (N-m); Gyroscopic moment about z ; l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['MFbxr']        = False     # (N-m); Gyroscopic moment about x ; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system 
BeamDyn_Nodes['MFbyr']        = False     # (N-m); Gyroscopic moment about y ; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system 
BeamDyn_Nodes['MFbzr']        = False     # (N-m); Gyroscopic moment about z ; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system 
BeamDyn_Nodes['FFcxl']        = False     # (N); Elastic restoring force Fc x ; l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['FFcyl']        = False     # (N); Elastic restoring force Fc y ; l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['FFczl']        = False     # (N); Elastic restoring force Fc z ; l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['FFcxr']        = False     # (N); Elastic restoring force Fc x ; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system 
BeamDyn_Nodes['FFcyr']        = False     # (N); Elastic restoring force Fc y ; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system 
BeamDyn_Nodes['FFczr']        = False     # (N); Elastic restoring force Fc z ; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system 
BeamDyn_Nodes['MFcxl']        = False     # (N-m);   Elastic restoring moment Fc about x ; l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['MFcyl']        = False     # (N-m);   Elastic restoring moment Fc about y ; l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['MFczl']        = False     # (N-m);   Elastic restoring moment Fc about z ; l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['MFcxr']        = False     # (N-m);   Elastic restoring moment Fc about x ; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system 
BeamDyn_Nodes['MFcyr']        = False     # (N-m);   Elastic restoring moment Fc about y ; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system 
BeamDyn_Nodes['MFczr']        = False     # (N-m);   Elastic restoring moment Fc about z ; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system 
BeamDyn_Nodes['FFdxl']        = False     # (N);   Elastic restoring force Fd x ; l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['FFdyl']        = False     # (N);   Elastic restoring force Fd y ; l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['FFdzl']        = False     # (N);   Elastic restoring force Fd z ; l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['FFdxr']        = False     # (N);   Elastic restoring force Fd x ; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system 
BeamDyn_Nodes['FFdyr']        = False     # (N);   Elastic restoring force Fd y ; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system 
BeamDyn_Nodes['FFdzr']        = False     # (N);   Elastic restoring force Fd z ; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system 
BeamDyn_Nodes['MFdxl']        = False     # (N-m);   Elastic restoring moment Fd about x ; l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['MFdyl']        = False     # (N-m);   Elastic restoring moment Fd about y ; l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['MFdzl']        = False     # (N-m);   Elastic restoring moment Fd about z ; l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['MFdxr']        = False     # (N-m);   Elastic restoring moment Fd about x ; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system 
BeamDyn_Nodes['MFdyr']        = False     # (N-m);   Elastic restoring moment Fd about y ; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system 
BeamDyn_Nodes['MFdzr']        = False     # (N-m);   Elastic restoring moment Fd about z ; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system 
BeamDyn_Nodes['FFgxl']        = False     # (N);   Gravity force x ; l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['FFgyl']        = False     # (N);   Gravity force y ; l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['FFgzl']        = False     # (N);   Gravity force z ; l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['FFgxr']        = False     # (N);   Gravity force x ; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system 
BeamDyn_Nodes['FFgyr']        = False     # (N);   Gravity force y ; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system 
BeamDyn_Nodes['FFgzr']        = False     # (N);   Gravity force z ; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system 
BeamDyn_Nodes['MFgxl']        = False     # (N-m);   Gravity moment about x ; l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['MFgyl']        = False     # (N-m);   Gravity moment about y ; l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['MFgzl']        = False     # (N-m);   Gravity moment about z ; l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['MFgxr']        = False     # (N-m);   Gravity moment about x ; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system 
BeamDyn_Nodes['MFgyr']        = False     # (N-m);   Gravity moment about y ; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system 
BeamDyn_Nodes['MFgzr']        = False     # (N-m);   Gravity moment about z ; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system 
BeamDyn_Nodes['FFixl']        = False     # (N);   Inertial force x ; l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['FFiyl']        = False     # (N);   Inertial force y ; l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['FFizl']        = False     # (N);   Inertial force z ; l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['FFixr']        = False     # (N);   Inertial force x ; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system 
BeamDyn_Nodes['FFiyr']        = False     # (N);   Inertial force y ; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system 
BeamDyn_Nodes['FFizr']        = False     # (N);   Inertial force z ; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system 
BeamDyn_Nodes['MFixl']        = False     # (N-m);   Inertial moment about x ; l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['MFiyl']        = False     # (N-m);   Inertial moment about y ; l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['MFizl']        = False     # (N-m);   Inertial moment about z ; l: a floating coordinate system local to the deflected beam
BeamDyn_Nodes['MFixr']        = False     # (N-m);   Inertial moment about x ; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system 
BeamDyn_Nodes['MFiyr']        = False     # (N-m);   Inertial moment about y ; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system 
BeamDyn_Nodes['MFizr']        = False     # (N-m);   Inertial moment about z ; r: a floating reference coordinate system fixed to the root of the moving beam; when coupled to FAST for blades, this is equivalent to the IEC blade (b) coordinate system 


""" ElastoDyn_Nodes """
ElastoDyn_Nodes = {}

#  Local Span Motions
ElastoDyn_Nodes['ALx']        = False     # (m/s^2); local flapwise acceleration (absolute) of node; Directed along the local xb-axis
ElastoDyn_Nodes['Ax']         = False     # (m/s^2); local flapwise acceleration (absolute) of node; Directed along the local xb-axis
ElastoDyn_Nodes['ALy']        = False     # (m/s^2); local flapwise acceleration (absolute) of node; Directed along the local yb-axis
ElastoDyn_Nodes['Ay']         = False     # (m/s^2); local flapwise acceleration (absolute) of node; Directed along the local yb-axis
ElastoDyn_Nodes['ALz']        = False     # (m/s^2); local flapwise acceleration (absolute) of node; Directed along the local zb-axis
ElastoDyn_Nodes['Az']         = False     # (m/s^2); local flapwise acceleration (absolute) of node; Directed along the local zb-axis
ElastoDyn_Nodes['TDx']        = False     # (m); local flapwise (translational) deflection (relative to the undeflected position) of node; Directed along the xb-axis
ElastoDyn_Nodes['UxB']        = False     # (m); local flapwise (translational) deflection (relative to the undeflected position) of node; Directed along the xb-axis
ElastoDyn_Nodes['TDy']        = False     # (m); local edgewise (translational) deflection (relative to the undeflected position) of node; Directed along the yb-axis
ElastoDyn_Nodes['UyB']        = False     # (m); local edgewise (translational) deflection (relative to the undeflected position) of node; Directed along the yb-axis
ElastoDyn_Nodes['TDz']        = False     # (m); local axial (translational) deflection (relative to the undeflected position) of node; Directed along the zb-axis
ElastoDyn_Nodes['UzB']        = False     # (m); local axial (translational) deflection (relative to the undeflected position) of node; Directed along the zb-axis
ElastoDyn_Nodes['RDx']        = False     # (deg); Local rotational displacement about x-axis (relative to undeflected); About the local xb-axis
ElastoDyn_Nodes['Rx']         = False     # (deg); Local rotational displacement about x-axis (relative to undeflected); About the local xb-axis
ElastoDyn_Nodes['RDy']        = False     # (deg); Local rotational displacement about y-axis (relative to undeflected); About the local yb-axis
ElastoDyn_Nodes['Ry']         = False     # (deg); Local rotational displacement about y-axis (relative to undeflected); About the local yb-axis
ElastoDyn_Nodes['RDz']        = False     # (deg); Local rotational displacement about z-axis (relative to undeflected); About the local zb-axis
ElastoDyn_Nodes['Rz']         = False     # (deg); Local rotational displacement about z-axis (relative to undeflected); About the local zb-axis

#  Local Span Loads
ElastoDyn_Nodes['MLx']        = False     # (kN-m);  local edgewise moment at node; About the local xb-axis
ElastoDyn_Nodes['Mx']         = False     # (kN-m);  local edgewise moment at node; About the local xb-axis
ElastoDyn_Nodes['MLy']        = False     # (kN-m);  local flapwise moment at node; About the local yb-axis
ElastoDyn_Nodes['My']         = False     # (kN-m);  local flapwise moment at node; About the local yb-axis
ElastoDyn_Nodes['MLz']        = False     # (kN-m);  local pitching moment at node; About the local zb-axis
ElastoDyn_Nodes['MLzNT']      = False     # (kN-m);  local pitching moment at node; About the local zb-axis
ElastoDyn_Nodes['MzL']        = False     # (kN-m);  local pitching moment at node; About the local zb-axis
ElastoDyn_Nodes['Mz']         = False     # (kN-m);  local pitching moment at node; About the local zb-axis
ElastoDyn_Nodes['FLx']        = False     # (kN);  local flapwise shear force at node; Directed along the local xb-axis
ElastoDyn_Nodes['Fx']         = False     # (kN);  local flapwise shear force at node; Directed along the local xb-axis
ElastoDyn_Nodes['FLy']        = False     # (kN);  local edgewise shear force at node; Directed along the local yb-axis
ElastoDyn_Nodes['Fy']         = False     # (kN);  local edgewise shear force at node; Directed along the local yb-axis
ElastoDyn_Nodes['FLz']        = False     # (kN);  local axial force at node; Directed along the local zb-axis
ElastoDyn_Nodes['FLzNT']      = False     # (kN);  local axial force at node; Directed along the local zb-axis
ElastoDyn_Nodes['FzL']        = False     # (kN);  local axial force at node; Directed along the local zb-axis
ElastoDyn_Nodes['Fz']         = False     # (kN);  local axial force at node; Directed along the local zb-axis
ElastoDyn_Nodes['MLxNT']      = False     # (kN-m); Edgewise moment in local coordinate system (initial structural twist removed); About the local xb-axis
ElastoDyn_Nodes['MxL']        = False     # (kN-m); Edgewise moment in local coordinate system (initial structural twist removed); About the local xb-axis
ElastoDyn_Nodes['MlyNT']      = False     # (kN-m); Flapwise shear moment in local coordinate system (initial structural twist removed); About the local yb-axis
ElastoDyn_Nodes['MyL']        = False     # (kN-m); Flapwise shear moment in local coordinate system (initial structural twist removed); About the local yb-axis
ElastoDyn_Nodes['FLxNT']      = False     # (kN); Flapwise shear force in local coordinate system (initial structural twist removed); Directed along the local xb-axis
ElastoDyn_Nodes['FxL']        = False     # (kN); Flapwise shear force in local coordinate system (initial structural twist removed); Directed along the local xb-axis
ElastoDyn_Nodes['FlyNT']      = False     # (kN); Edgewise shear force in local coordinate system (initial structural twist removed); Directed along the local yb-axis
ElastoDyn_Nodes['FyL']        = False     # (kN); Edgewise shear force in local coordinate system (initial structural twist removed); Directed along the local yb-axis

""" MoorDyn """
# THIS IS NOT A COMPLETE LIST!
# the "flexible naming system" discussed on page 7-8 of the documentation is not included
# https://moordyn.readthedocs.io/en/latest/inputs.html#id5

# also assuming that like other OpenFAST variables, it is limited to 9 output locations per veriable, i.e. FairTen1-FairTen9
# TODO: Handle the flexible outputs for moordyn. This will require a different approach than the current dictionary structure.
# Right now a hackish way is used in the reader 
# Update the message in FAST_writer.write_MoorDyn() when this is finished

MoorDyn = {}
MoorDyn['FairTen1']            = False     # (); ; 
MoorDyn['FairTen2']            = False     # (); ; 
MoorDyn['FairTen3']            = False     # (); ; 
MoorDyn['FairTen4']            = False     # (); ; 
MoorDyn['FairTen5']            = False     # (); ; 
MoorDyn['FairTen6']            = False     # (); ; 
MoorDyn['FairTen7']            = False     # (); ; 
MoorDyn['FairTen8']            = False     # (); ; 
MoorDyn['FairTen9']            = False     # (); ; 
MoorDyn['AnchTen1']            = False     # (); ; 
MoorDyn['AnchTen2']            = False     # (); ; 
MoorDyn['AnchTen3']            = False     # (); ; 
MoorDyn['AnchTen4']            = False     # (); ; 
MoorDyn['AnchTen5']            = False     # (); ; 
MoorDyn['AnchTen6']            = False     # (); ; 
MoorDyn['AnchTen7']            = False     # (); ; 
MoorDyn['AnchTen8']            = False     # (); ; 
MoorDyn['AnchTen9']            = False     # (); ; 





""" ExtPtfm """
# THIS IS NOT A COMPLETE LIST!
# Need to handle in different way based on documentaion here: https://openfast.readthedocs.io/en/main/source/user/extptfm/input_files.html#output-channels
# TODO: Handle the flexible outputs for ExtPtfm. This will require a different approach than the current dictionary structure.

ExtPtfm = {}
ExtPtfm['IntrfFx']                = False #                  - Platform interface force  - Directed along the x-direction  (N)
ExtPtfm['IntrfFy']                = False #                  - Platform interface force  - Directed along the y-direction  (N)
ExtPtfm['IntrfFz']                = False #                  - Platform interface force  - Directed along the z-direction  (N)
ExtPtfm['IntrfMx']                = False #                  - Platform interface moment - Directed along the x-direction  (Nm)
ExtPtfm['IntrfMy']                = False #                  - Platform interface moment - Directed along the y-direction  (Nm)
ExtPtfm['IntrfMz']                = False #                  - Platform interface moment - Directed along the z-direction  (Nm)
ExtPtfm['InpF_Fx']                = False #                  - Reduced Input force at interface point - Directed along the x-direction  (N)
ExtPtfm['InpF_Fy']                = False #                  - Reduced Input force at interface point - Directed along the y-direction  (N)
ExtPtfm['InpF_Fz']                = False #                  - Reduced Input force at interface point - Directed along the z-direction  (N)
ExtPtfm['InpF_Mx']                = False #                  - Reduced Input moment at interface point - Directed along the x-direction  (Nm)
ExtPtfm['InpF_My']                = False #                  - Reduced Input moment at interface point - Directed along the y-direction  (Nm)
ExtPtfm['InpF_Mz']                = False #                  - Reduced Input moment at interface point - Directed along the z-direction  (Nm)
ExtPtfm['CBQ_001']                = False #                  - Modal displacement of internal Craig-Bampton mode number XXX  (-)
ExtPtfm['CBQ_002']                = False #                  - Modal displacement of internal Craig-Bampton mode number XXX  (-)
ExtPtfm['CBQ_003']                = False #                  - Modal displacement of internal Craig-Bampton mode number XXX  (-)
ExtPtfm['CBQ_004']                = False #                  - Modal displacement of internal Craig-Bampton mode number XXX  (-)
ExtPtfm['CBQ_005']                = False #                  - Modal displacement of internal Craig-Bampton mode number XXX  (-)
ExtPtfm['CBQ_006']                = False #                  - Modal displacement of internal Craig-Bampton mode number XXX  (-)
ExtPtfm['CBQ_007']                = False #                  - Modal displacement of internal Craig-Bampton mode number XXX  (-)
ExtPtfm['CBQ_010']                = False #                  - Modal displacement of internal Craig-Bampton mode number XXX  (-)
ExtPtfm['CBQ_011']                = False #                  - Modal displacement of internal Craig-Bampton mode number XXX  (-)
ExtPtfm['CBQ_012']                = False #                  - Modal displacement of internal Craig-Bampton mode number XXX  (-)
ExtPtfm['CBQ_013']                = False #                  - Modal displacement of internal Craig-Bampton mode number XXX  (-)
ExtPtfm['CBQ_014']                = False #                  - Modal displacement of internal Craig-Bampton mode number XXX  (-)
ExtPtfm['CBQ_015']                = False #                  - Modal displacement of internal Craig-Bampton mode number XXX  (-)
ExtPtfm['CBQ_016']                = False #                  - Modal displacement of internal Craig-Bampton mode number XXX  (-)
ExtPtfm['CBQ_017']                = False #                  - Modal displacement of internal Craig-Bampton mode number XXX  (-)
ExtPtfm['CBQ_020']                = False #                  - Modal displacement of internal Craig-Bampton mode number XXX  (-)
ExtPtfm['CBQ_021']                = False #                  - Modal displacement of internal Craig-Bampton mode number XXX  (-)
ExtPtfm['CBQ_022']                = False #                  - Modal displacement of internal Craig-Bampton mode number XXX  (-)
ExtPtfm['CBQ_023']                = False #                  - Modal displacement of internal Craig-Bampton mode number XXX  (-)
ExtPtfm['CBQ_024']                = False #                  - Modal displacement of internal Craig-Bampton mode number XXX  (-)
ExtPtfm['CBQ_025']                = False #                  - Modal displacement of internal Craig-Bampton mode number XXX  (-)
ExtPtfm['CBF_001']                = False #                  - Modal force        on internal Craig-Bampton mode number XXX  (-)
ExtPtfm['CBF_002']                = False #                  - Modal force        on internal Craig-Bampton mode number XXX  (-)
ExtPtfm['CBF_003']                = False #                  - Modal force        on internal Craig-Bampton mode number XXX  (-)
ExtPtfm['CBF_004']                = False #                  - Modal force        on internal Craig-Bampton mode number XXX  (-)
ExtPtfm['CBF_005']                = False #                  - Modal force        on internal Craig-Bampton mode number XXX  (-)
ExtPtfm['CBF_006']                = False #                  - Modal force        on internal Craig-Bampton mode number XXX  (-)
ExtPtfm['CBF_007']                = False #                  - Modal force        on internal Craig-Bampton mode number XXX  (-)
ExtPtfm['CBF_010']                = False #                  - Modal force        on internal Craig-Bampton mode number XXX  (-)
ExtPtfm['CBF_011']                = False #                  - Modal force        on internal Craig-Bampton mode number XXX  (-)
ExtPtfm['CBF_012']                = False #                  - Modal force        on internal Craig-Bampton mode number XXX  (-)
ExtPtfm['CBF_013']                = False #                  - Modal force        on internal Craig-Bampton mode number XXX  (-)
ExtPtfm['CBF_014']                = False #                  - Modal force        on internal Craig-Bampton mode number XXX  (-)
ExtPtfm['CBF_015']                = False #                  - Modal force        on internal Craig-Bampton mode number XXX  (-)
ExtPtfm['CBF_016']                = False #                  - Modal force        on internal Craig-Bampton mode number XXX  (-)
ExtPtfm['CBF_017']                = False #                  - Modal force        on internal Craig-Bampton mode number XXX  (-)
ExtPtfm['CBF_020']                = False #                  - Modal force        on internal Craig-Bampton mode number XXX  (-)
ExtPtfm['CBF_021']                = False #                  - Modal force        on internal Craig-Bampton mode number XXX  (-)
ExtPtfm['CBF_022']                = False #                  - Modal force        on internal Craig-Bampton mode number XXX  (-)
ExtPtfm['CBF_023']                = False #                  - Modal force        on internal Craig-Bampton mode number XXX  (-)
ExtPtfm['CBF_024']                = False #                  - Modal force        on internal Craig-Bampton mode number XXX  (-)
ExtPtfm['CBF_025']                = False #                  - Modal force        on internal Craig-Bampton mode number XXX  (-)
ExtPtfm['WavElev']                = False #                  - Wave elevation                                                (m)

""" AeroDisk """
AeroDisk = {}

# All channels
AeroDisk['ADSpeed']           = False     # (rpm); Actuator disk rotational speed; 
AeroDisk['ADTSR']             = False     # (-); Actuator disk tip-speed ratio; 
AeroDisk['ADPitch']           = False     # (deg); Actuator disk collective blade-pitch angle; 
AeroDisk['ADVWindx']          = False     # (m/s); Actuator-disk-average wind velocity; local coordinate system - X
AeroDisk['ADVWindy']          = False     # (m/s); Actuator-disk-average wind velocity; local coordinate system - Y
AeroDisk['ADVWindz']          = False     # (m/s); Actuator-disk-average wind velocity; local coordinate system - Z
AeroDisk['ADVWindxi']         = False     # (m/s); Actuator-disk-average wind velocity; global (inertial) coordinate system - X
AeroDisk['ADVWindyi']         = False     # (m/s); Actuator-disk-average wind velocity; global (inertial) coordinate system - Y
AeroDisk['ADVWindzi']         = False     # (m/s); Actuator-disk-average wind velocity; global (inertial) coordinate system - Z
AeroDisk['ADSTVx']            = False     # (m/s); Actuator-disk structural translation velocity; local coordinate system - X
AeroDisk['ADSTVy']            = False     # (m/s); Actuator-disk structural translation velocity; local coordinate system - Y
AeroDisk['ADSTVz']            = False     # (m/s); Actuator-disk structural translation velocity; local coordinate system - Z
AeroDisk['ADSTVxi']           = False     # (m/s); Actuator-disk structural translation velocity; global (inertial) coordinate system - X
AeroDisk['ADSTVyi']           = False     # (m/s); Actuator-disk structural translation velocity; global (inertial) coordinate system - Y
AeroDisk['ADSTVzi']           = False     # (m/s); Actuator-disk structural translation velocity; global (inertial) coordinate system - Z
AeroDisk['ADVRel']            = False     # (m/s); Actuator-disk -average relative wind speed; 
AeroDisk['ADSkew']            = False     # (deg); Actuator-disk inflow-skew angle; 
AeroDisk['ADYawErr']          = False     # (deg); Actuator-disk yaw-error angle; 
AeroDisk['ADCp']              = False     # (-); Actuator-disk coeficent of power; 
AeroDisk['ADCt']              = False     # (-); Actuator-disk coeficent of thrust; 
AeroDisk['ADCq']              = False     # (-); Actuator-disk coeficent of torque; 
AeroDisk['ADFx']              = False     # (N); Actuator-disk aerodynamic force; local coordinate system - X
AeroDisk['ADFy']              = False     # (N); Actuator-disk aerodynamic force; local coordinate system - Y
AeroDisk['ADFz']              = False     # (N); Actuator-disk aerodynamic force; local coordinate system - Z
AeroDisk['ADFxi']             = False     # (N); Actuator-disk aerodynamic force; global (inertial) coordinate system - X
AeroDisk['ADFyi']             = False     # (N); Actuator-disk aerodynamic force; global (inertial) coordinate system - Y
AeroDisk['ADFzi']             = False     # (N); Actuator-disk aerodynamic force; global (inertial) coordinate system - Z
AeroDisk['ADMx']              = False     # (N-m); Actuator-disk aerodynamic moment; local coordinate system - X
AeroDisk['ADMy']              = False     # (N-m); Actuator-disk aerodynamic moment; local coordinate system - Y
AeroDisk['ADMz']              = False     # (N-m); Actuator-disk aerodynamic moment; local coordinate system - Z
AeroDisk['ADMxi']             = False     # (N-m); Actuator-disk aerodynamic moment; global (inertial) coordinate system - X
AeroDisk['ADMyi']             = False     # (N-m); Actuator-disk aerodynamic moment; global (inertial) coordinate system - Y
AeroDisk['ADMzi']             = False     # (N-m); Actuator-disk aerodynamic moment; global (inertial) coordinate system - Z
AeroDisk['ADPower']           = False     # (W); Actuator-disk power; 


""" SimpleElastoDyn """
SimpleElastoDyn = {}

# Outputs
SimpleElastoDyn['Azimuth']    = False     # (deg); Rotor azimuth angle (position); 
SimpleElastoDyn['RotSpeed']   = False     # (rpm); Rotor azimuth angular speed; 
SimpleElastoDyn['LSSTipVxa']  = False     # (rpm); Rotor azimuth angular speed; 
SimpleElastoDyn['LSSTipVxs']  = False     # (rpm); Rotor azimuth angular speed; 
SimpleElastoDyn['LSSTipV']    = False     # (rpm); Rotor azimuth angular speed; 
SimpleElastoDyn['RotAcc']     = False     # (deg/s^2); Rotor azimuth angular acceleration; 
SimpleElastoDyn['LSSTipAxs']  = False     # (deg/s^2); Rotor azimuth angular acceleration; 
SimpleElastoDyn['LSSTipA']    = False     # (deg/s^2); Rotor azimuth angular acceleration; 
SimpleElastoDyn['LSSTipAxa']  = False     # (deg/s^2); Rotor azimuth angular acceleration; 
SimpleElastoDyn['GenSpeed']   = False     # (rpm); Angular speed of the high-speed shaft and generator; 
SimpleElastoDyn['HSShftV']    = False     # (rpm); Angular speed of the high-speed shaft and generator; 
SimpleElastoDyn['GenAcc']     = False     # (deg/s^2); Angular acceleration of the high-speed shaft and generator; 
SimpleElastoDyn['HSShftA']    = False     # (deg/s^2); Angular acceleration of the high-speed shaft and generator; 
SimpleElastoDyn['Yaw']        = False     # (deg); Commanded yaw position from controller; 
SimpleElastoDyn['YawRate']    = False     # (deg/s); commanded yaw rate from controller; 

# Blade Pitch Motions
SimpleElastoDyn['BldPitch1']  = False     # (deg); Blade 1 pitch angle (position); Positive towards feather about the minus zc1- and minus zb1-axes
SimpleElastoDyn['BlPitch1']   = False     # (deg); Blade 1 pitch angle (position); Positive towards feather about the minus zc1- and minus zb1-axes
SimpleElastoDyn['BldPitch2']  = False     # (deg); Blade 2 pitch angle (position); Positive towards feather about the minus zc2- and minus zb2-axes
SimpleElastoDyn['BlPitch2']   = False     # (deg); Blade 2 pitch angle (position); Positive towards feather about the minus zc2- and minus zb2-axes
SimpleElastoDyn['BldPitch3']  = False     # (deg); Blade 3 pitch angle (position); Positive towards feather about the minus zc3- and minus zb3-axes
SimpleElastoDyn['BlPitch3']   = False     # (deg); Blade 3 pitch angle (position); Positive towards feather about the minus zc3- and minus zb3-axes

# Hub and Rotor Loads
SimpleElastoDyn['RotTorq']    = False     # (kN-m); Low-speed shaft torque (this is constant along the shaft and is equivalent to the rotor torque); About the xa- and xs-axes
SimpleElastoDyn['LSShftTq']   = False     # (kN-m); Low-speed shaft torque (this is constant along the shaft and is equivalent to the rotor torque); About the xa- and xs-axes
SimpleElastoDyn['RotPwr']     = False     # (kW); Rotor power (this is equivalent to the low-speed shaft power); N/A
SimpleElastoDyn['LSShftPwr']  = False     # (kW); Rotor power (this is equivalent to the low-speed shaft power); N/A


""" Final Output Dictionary """
FstOutput = {}
FstOutput['AeroDyn']          = AeroDyn
FstOutput['BeamDyn']          = BeamDyn
FstOutput['ElastoDyn']        = ElastoDyn
FstOutput['InflowWind']       = InflowWind
FstOutput['ServoDyn']         = ServoDyn
FstOutput['HydroDyn']         = HydroDyn
FstOutput['Morison']          = Morison
FstOutput['SeaState']         = SeaState
FstOutput['SubDyn']           = SubDyn
FstOutput['WAMIT']            = WAMIT
FstOutput['AeroDyn_Nodes']    = AeroDyn_Nodes
FstOutput['BeamDyn_Nodes']    = BeamDyn_Nodes
FstOutput['ElastoDyn_Nodes']  = ElastoDyn_Nodes
FstOutput['MoorDyn']          = MoorDyn
FstOutput['ExtPtfm']          = ExtPtfm
FstOutput['AeroDisk']         = AeroDisk
FstOutput['SimpleElastoDyn']  = SimpleElastoDyn